ABSTRACT Title of Document: PEDOGENESIS, INVENTORY, AND UTILIZATION OF SUBAQUEOUS SOILS IN CHINCOTEAGUE BAY, MARYLAND Danielle Marie Balduff, Ph.D., 2007 Directed By: Professor Martin C. Rabenhorst, Department of Environmental Science and Technology Chincoteague Bay is the largest (19,000 ha) of Maryland?s inland coastal bays bounded by Assateague Island to the east and the Maryland mainland to the west. It is connected to the Atlantic Ocean by the Ocean City inlet to the north and the Chincoteague inlet to the south. Water depth ranges mostly from 1.0 to 2.5 meters mean sea level (MSL). The objectives of this study were to identify the subaqueous landforms, evaluate the suitability of existing subaqueous soil-landscape models, develop a soils map, and demonstrate the usefulness of subaqueous soils information. Bathymetric data collected by the Maryland Geological Survey in 2003 were used to generate a digital elevation model (DEM) of Chincoteague Bay. The DEM was used, in conjunction with false color infrared photography to identify subaqueous landforms based on water depth, slope, landscape shape, depositional environment, and geographical setting (proximity to other landforms). The eight such landforms identified were barrier cove, lagoon bottom, mainland cove, paleo-flood tidal delta, shoal, storm-surge washover fan flat, storm-surge washover fan slope, and submerged headland. Previously established soil-landscape models were evaluated and utilized to create a soils map of the area. Soil profile descriptions were collected at 163 locations throughout Chincoteague Bay. Pedons representative of major landforms were characterized for a variety of chemical, physical and mineralogical properties. Initially classification using Soil Taxonomy (Soil Survey Staff, 2006) identified the major soils as Typic Sulfaquents, Haplic Sulfaquents, Sulfic Hydraquents, and Thapto-Histic Sulfaquents. Using a proposed modification to Soil Taxonomy designed to better accommodate subaqueous soils with the new suborder of Wassents, soils of Chincoteague Bay were primarily classified as Fluvic Sulfiwassents, Haplic Sulfiwassents, Thapto-Histic Sulfiwassents, Sulfic Hydrowassents, and Sulfic Psammowassents. To illustrate the application of subaqueous soils information, the suitability of soils for submerged aquatic vegetation (SAV) habitat was assessed, based upon past and current growth patterns in Chincoteague Bay and sediment properties known to affect SAV establishment and growth. The refined soil-landscape models and extensive soil characterization obtained in this study have advanced our understanding of subaqueous soils in coastal lagoon systems, and should prove valuable to coastal specialists managing these critical resources. PEDOGENESIS, INVENTORY, AND UTILIZATION OF SUBAQUEOUS SOILS IN CHINCOTEAGUE BAY, MARYLAND By Danielle Marie Balduff Dissertation submitted to the Faculty of the Graduate School of the University of Maryland, College Park, in partial fulfillment of the requirements for the degree of Doctor of Philosophy 2007 Advisory Committee: Professor Martin C. Rabenhorst, Chair Professor Bruce James Dr. Douglas Levin Dr. Roberta Marinelli Assistant Professor Brian Needelman Associate Professor Karen Prestegaard ? Copyright by Danielle Marie Balduff 2007 ii Acknowledgements This research was funded through a grant from the U.S. Department of Agriculture, Natural Resources Conservation Service. Thank you for your support. I sincerely thank all who have contributed to my success. Martin Rabenhorst, my advisor, who has passed on a great deal of knowledge and excitement for this field and who was an excellent and patient editor of this work, thank you for being a wonderful mentor. To my committee members, Bruce James, Doug Levin, Roberta Marinelli, Brian Needelman, and Karen Prestegaard, for teaching me concepts that have helped to make me a more well-rounded scientist and for your feedback and guidance on this work. I wish to thank Del Fanning for teaching me how to play bridge and for sharing his knowledge about pedology and mineralogy. I wish to express my appreciation to Richard Weismiller for allowing me to assist in teaching ENST 105 and for reminding me how much I like to teach and why I decided to pursue my Ph D in soil science. I wish to thank Susan Demas for providing me with a place to stay at her home during the summer of 2005, while I was doing my field work, thank you for your hospitality and your friendship. To Amanda Haase and Ross McAllen, my summer field assistants, who helped collect, describe, and sample the soils in Chincoteague Bay, thank you for having a great attitude and for your flexibility in dealing with boat engine problems, bad weather, and long days when the weather was perfect. To Cary Coppock for teaching me how to collect and describe subaqueous soils and to drive a boat and pull a trailer, thanks for all of your help. I wish to express my iii appreciation to Mark Stolt and Phil King teaching me how to describe and classify subaqueous soils, create subaqueous soil series, and in understanding landscape-soil relationships. I wish to thank Patrick Morton, Adam Gray, Rebecca Bourgault, Phil Zurheide, Karen Vaughan, John Wah, and Rosalynd Orr for your friendship, advice, and help in finishing my doctoral work. iv Table of Contents Acknowledgements............................................................................................................. ii Table of Contents...............................................................................................................iv List of Tables ..................................................................................................................... vi List of Figures.................................................................................................................... ix Chapter 1: Introduction....................................................................................................... 1 Background..................................................................................................................... 1 Study Area ......................................................................................................................2 Objectives ....................................................................................................................... 7 Chapter 2: Literature Review.............................................................................................. 8 Barrier Islands and Coastal Lagoons .............................................................................. 8 Chincoteague Bay ..................................................................................................... 14 Sediment Mapping in the Coastal Bays.................................................................... 19 Limitations of Previous Approaches......................................................................... 26 Subaqueous Soils .......................................................................................................... 30 Pedogenic Paradigm Extended to Subaqueous Environments.................................. 36 State Factors of Subaqueous Soil Formation............................................................ 38 Research on Subaqueous Soils.................................................................................. 41 Submerged Aquatic Vegetation Habitat Requirements ............................................ 49 Chapter 3: Topographic Analysis and Subaqueous Landforms........................................ 63 Introduction................................................................................................................... 63 Materials and Methods.................................................................................................. 65 Study Area ................................................................................................................ 65 Bathymetric Data Collection..................................................................................... 68 Evaluation of Maryland Geologic Survey Data........................................................ 73 Landform Delineation............................................................................................... 73 Results and Discussion ................................................................................................. 74 Subaqueous Topographic Maps................................................................................ 74 Subaqueous Landforms............................................................................................. 79 Conclusions................................................................................................................... 86 Chapter 4: Characterization and Classification of Subaqueous Soils in Chincoteague Bay, MD .................................................................................................................................... 87 Introduction................................................................................................................... 87 Materials and Methods.................................................................................................. 92 Study Site.................................................................................................................. 92 Soil Sampling............................................................................................................ 92 Laboratory Analysis.................................................................................................. 94 Grain Size Distribution ............................................................................................. 98 Results and Discussion ................................................................................................. 99 Characterization of Subaqueous Soils ...................................................................... 99 Carbon Distribution in Subaqueous Soils............................................................... 132 Classification Using Current Soil Taxonomy.......................................................... 147 Classification Using Proposed Changes to Soil Taxonomy .................................... 166 v Development of Subaqueous Soil Series ................................................................ 173 Conclusions................................................................................................................. 189 Chapter 5: Subaqueous Soil-Landscape Relationships in Chincoteague Bay, MD....... 192 Introduction................................................................................................................. 192 Materials and Methods................................................................................................ 200 Study Site................................................................................................................ 200 Soil Sampling Techniques and Laboratory Analysis.............................................. 201 Soil-Landscape Analysis......................................................................................... 203 Development of Soils Map ..................................................................................... 203 Results......................................................................................................................... 204 Subaqueous Soil-Landscape Relationships............................................................. 204 Buried Organic Soils............................................................................................... 213 Soil Map Unit Composition and Variability........................................................... 220 Discussion................................................................................................................... 234 Conclusions................................................................................................................. 244 Chapter 6: Utilization of Subaqueous Soils Information for Assessing Submerged Aquatic Vegetation Habitat............................................................................................. 246 Introduction................................................................................................................. 246 Water Quality Parameters....................................................................................... 246 Soil Parameters ....................................................................................................... 250 Uses of Soil Inventory Data.................................................................................... 259 Material and Methods ................................................................................................. 260 Study Site................................................................................................................ 260 Soils of Chincoteague Bay...................................................................................... 260 Submerged Aquatic Vegetation Information for Chincoteague Bay...................... 261 Analysis................................................................................................................... 262 Results......................................................................................................................... 262 Discussion................................................................................................................... 278 Conclusions................................................................................................................. 281 Chapter 7: Dissertation Summary and Conclusions ....................................................... 283 List of Appendices .......................................................................................................... 289 Appendix A: Proposed Changes to Soil Taxonomy ........................................................ 290 Appendix B: Landforms, Map Units, and Classification of Soil Pedons ....................... 298 Appendix C: Soil Morphological Descriptions............................................................... 308 Appendix D: Total Carbon, Organic Carbon, and Calcium Carbonate Data.................. 468 Appendix E: Moist Incubation pH Data ......................................................................... 484 Appendix F: Salinity Data .............................................................................................. 492 Appendix G: Moisture Content and Bulk Density Data ................................................. 499 Appendix H: Particle-Size Data...................................................................................... 509 References....................................................................................................................... 521 vi List of Tables Table 2-1. Classification of Sub-Aqueous soils in Kubiena?s Soils of Europe (Modified from Kubiena, 1953)???????????????????????..32 Table 2-2. Classification of Subhydric Soils in the Federal Republic of Germany Soil Categories (Modified from Muckenhausen, 1965). The types of subhydric soils are based on Kubiena?s (1953) classification of sub-aqueous soils?????...33 Table 2-3. Landforms and the associated soils found in Sinepuxent Bay, Maryland (Modified from Demas, 1999)???????????????????...44 Table 2-4. Landforms and the associated soils found in Ninigret Pond, Rhode Island (Modified from Bradley and Stolt, 2003)???????????????..46 Table 2-5. Landforms and the associated soils found in Taunton Bay, Maine (Modified from Osher and Flannagan, 2007)??????????????????.48 Table 2-6. Summary of sediment characteristics defining habitat constraints for submerged aquatic vegetation in fresh water and marine environments???...50 Table 3-1. Subaqueous landforms commonly found in Atlantic coastal lagoons. Definitions adapted from Subaqueous Soils Subcommittee, 2005??????66 Table 3-2. Subaqueous landscape units and cumulative extent in Chincoteague Bay, MD??????????????????????????????.81 Table 4-1. Classification of Sub-Aqueous soils in Kubiena?s Soils of Europe (Modified from Kubiena, 1953)???????????????????????..89 Table 4-2. Field textures compared to textures from particle-size data for selected horizons collected in the summers of 2004 and 2005 in Chincoteague Bay?...101 Table 4-3. The length of time for 163 samples incubated under moist aerobic conditions to drop below a pH of 4. Only 51% of these samples that would eventually show a drop in pH to below 4 did so within the prescribed eight weeks??????.122 Table 4-4. Acid volatile sulfide (monosulfides) and chromium reducible sulfide (disulfides) concentrations from the storm-surge washover fan flat (CB01), lagoon bottom (CB18 and CB58), barrier cove (CB52) and mainland cove (CB11)?..124 Table 4-5. Quantities of organic carbon stored in the upper 1 m of the soil within various landforms described in Chincoteague Bay??????????????..145 Table 4-6. That portion of Soil Taxonomy (2006) used in the classification of 146 subaqueous soils in Chincoteague Bay. Note that sulfi great groups of Saprists and Aquents are distinguished by the presence of sulfidic materials in the upper 50 cm of the soil???????????????????????? 148 Table 4-7. Particle-size distribution for select samples used for assessing the mineralogy of subaqueous soils???????????????????????..151 Table 4-8. Mineralogical composition of the select samples based on the grain counts of the two or three dominant fractions that comprised 67% or more (by weight) of all fractions from 0.02 to 2.0 mm???????????????????.152 vii Table 4-9. Mineralogical composition of the select samples based on the grain counts of the dominant two or three dominant fractions that comprised 67% or more (by weight) of all fractions from 0.02 to 2.0 mm. The values represent the weighted average of the mineral fractions based on the horizon thickness in the control section. The pedons are not dominated by a single mineral and were classified as having a mixed mineralogy????????????????????..153 Table 4-10. Semi-quantitative mineral estimates of the fine silt (0.002 to 0.02 mm) and coarse silt (0.02 to 0.05 mm) fractions of selected samples. The composition of these fractions indicates that no single mineral fraction was dominant???...154 Table 4-11. Semi-quantitative mineral estimates of the clay fraction of selected samples. The composition of these fractions indicates that no single mineral fraction was dominant. The jarosite peaks are an artifact in the clay fraction created during the removal of the organic matter from sample CB11 Cg1 and Cg2??????159 Table 4-12. Classification of 146 subaqueous soils described in Chincoteague Bay to the family level using current Soil Taxonomy. Numbers in parenthesis indicate the number of pedons in each taxon??????????????????..168 Table 4-13. That portion of the proposed changes to Soil Taxonomy (2006) used in the classification of 146 subaqueous soils in Chincoteague Bay???????...169 Table 4-14. Classification of 146 subaqueous soils described in Chincoteague Bay using the proposed classification. Numbers in parenthesis indicate the number of pedons in the taxon??????????????????????????...171 Table 4-15. New soil series proposed for use in Chincoteague Bay, Maryland???????????????????????????..175 Table 4-16. Differentiating criteria for proposed and established soil series for Chincoteague Bay, MD. Those soil series that are already officially established are shown as shaded???????????????????????.176 Table 4-17. Field morphological description of subaqueous soil profile CB97. Modal pedon for the Truitt Series????????????????????...181 Table 4-18. Field morphological description of subaqueous soil profile CB18. Modal pedon for the Tingles Series????????????????????182 Table 4-19. Field morphological description of subaqueous soil profile CB95. Modal pedon for the Coards Series????????????????????.183 Table 4-20. Field morphological description of subaqueous soil profile CB39. Modal pedon for the Middlemoor Series??????????????????184 Table 4-21. Field morphological description of subaqueous soil profile CB55. Modal pedon for the Cottman Series???????????????????..185 Table 4-22. Field morphological description of subaqueous soil profile CB56. Modal pedon for the Thorofare Series???????????????????186 Table 4-23. Field morphological description of subaqueous soil profile CB41. Modal pedon for the Figgs Series????????????????????...187 Table 4-24. Field morphological description of subaqueous soil profile CB146. Modal pedon for the Tumagan Series???????????????????.188 Table 5-1. Major landforms and the associated soils found in Sinepuxent Bay, Maryland (summarized from Demas, 1998)??????????????????193 viii Table 5-2. Major landforms and the associated soils found in Ninigret Pond, Rhode Island (summarized from Bradley and Stolt, 2003)???????????.195 Table 5-3. Major landforms and associated soils found in Taunton Bay, Maine (summarized from Osher and Flannagan, 2007)????????????..198 Table 5-4. Classification of subaqueous soil profiles in each Chincoteague Bay landform. All profiles classified according to the Proposed Changes to Soil Taxonomy (Northeast Regional Cooperative Soil Survey Subaqueous Soils Committee, 2007)?????????????????????????????205 Table 5-5. Weighted fine sand content (0-50 cm) for the subaqueous soil profiles located on the storm-surge washover fan flats????????????????.208 Table 5-6. Carbon-14 dates for four buried organic horizons located in Chincoteague Bay, one buried organic horizon located in an adjacent tidal marsh area, one wood fragment from adjacent Sinepuxent Bay, MD (Demas and Rabenhorst, 1999), and two peats from Hell Hook Marsh and Cedar Creek Marsh (Dorchester County), MD (Hussein, 1996). Average sea level rise rates were also calculated for these horizons????????????????????????????221 Table 5-7. Subaqueous Soil Mapping Legend for Chincoteague Bay, Maryland??...224 Table 5-8. Soil taxonomic classifications and components of each of the 10 soil map units identified in Chincoteague Bay???????????????????227 Table 6-1. Habitat recommendations for submerged aquatic vegetation growth and survival in the polyhaline portion of Chesapeake Bay developed by the Chesapeake Bay Program (modified from Batiuk, 2000)?????????249 Table 6-2. Summary of soil/sediment characteristics defining habitat constraints for submerged aquatic vegetation in fresh water and marine environments???.251 Table 6-3. Summary of soil properties based on a literature review of Zostera marina (eelgrass) and Ruppia maritima (widgeon grass) which were used to determine the suitability of the soils in Chincoteague Bay????????????...264 Table 6-4. Soil map units and favorable and limiting soil characteristics that may impact SAV growth in Chincoteague Bay?????????????????...265 ix List of Figures Figure 1-1. Map of Maryland coastal lagoons. The study area is highlight in red. (Modified from Wazniak et al., 2004)?????????????????.3 Figure 2-1. Idealized diagram of Gilbert?s Theory of barrier island formation from a spit through sediments transported by littoral and longshore currents. 1 and 2) The spit develops in the direction of longshore sediment transport. 3) The spit is breached to form a barrier island (Modified from Hoyt, 1967)???????????10 Figure 2-2. Illustration of a wave-dominated inlet and the major sedimentary features identified (From Davis, 1994)???..????????????????..13 Figure 2-3. Map of Chincoteague Bay, Maryland showing three major areas of marshes (Modified from Biggs, 1970)????????????????????.18 Figure 2-4. Historical record of the development of Middlemoor and the closing of Green Run Inlet (From Gawne, 1966)???????????????????..20 Figure 2-5. Locations of prior inlets once open, but now closed located on Assateague Island, Maryland (From Wells and Conkwright, 1999)??????????.21 Figure 2-6. Locations of borings from Biggs (1970)??????????????.22 Figure 2-7. Percent of sand in surficial sediments of Chincoteague Bay in 1976 (Modified from Bartberger, 1976). The location of a relict inlet, Green Run Inlet, is identified????????????????????????????24 Figure 2-8. Distribution of sediment type of surficial sediments of Chincoteague Bay based on Shepard?s classification scheme (Modified from Wells and Conkwright, 1999). The particle-size classes are: sand (2.0-0.63 mm); silt (0.63 to 0.004 mm); and clay (<0.004 mm)???????????????????????27 Figure 2-9. Percent of sand (>0.63 mm) in surficial sediments of Chincoteague Bay collected by Wells and Conkwright (1999). This map was created using the Maryland Geological Survey data set in ArcMap using the geostatistical analyst???????????........................................................................28 Figure 2-10. Synthesis of Jenny?s Factors of Soil Formation and Folger?s factors of estuarine sediment composition and distribution were used to create the Factors of Subaqueous Soil Formation. Jenny?s factors of soil formation included climate (C), organisms (O), relief (R), parent material (P), time (T), and dot factor ( . ). Folger?s factor of estuarine sediment composition and distribution included geology (G), hydrology (H), and bathymetry (B). The factors of subaqueous soil formation included climate (C), organisms (O), bathymetry (B), flow regime (F), parent material (P), time (T), water column attributes (W), and catastrophic events (E)??????????????..................................................................39 Figure 3-1. The Delmarva Peninsula and the inland coastal bays of Delaware, Maryland, and Virginia (Biggs, 1970)?????????????????????67 x Figure 3-2. Point data collected for the Maryland portion of Chincoteague Bay by the Maryland Geological Survey, from May through September 2003 using differential global positioning system techniques and digital dual frequency echo sounding equipment. Water level data was also collected at four locations within the study area and were used to correct the echo soundings for tide and wind offsets (Wells et al., 2004)?????????????????????.69 Figure 3-3. Location of bathymetric data collected in August and November, 2003 in a 4600 ha study area of Chincoteague Bay, MD using a fathometer that utilizes acoustic soundings. The average density of measurements was approximately 0.62 ha per sounding???????????????????????..70 Figure 3-4. Tide data collected in Chincoteague Bay during August, 2003 (A) and November, 2003 (B) near Public Landing, Maryland??????????...72 Figure 3-5. Subaqueous topographic map of Chincoteague Bay created by kriging the data we collected in ArcMap using geostatistical analyst. Contour intervals are 100 cm and were generated using spatial analyst surface analyst in ArcMap...?75 Figure 3-6. Subaqueous topographic map of Chincoteague Bay created by kriging the original Maryland Geologic Survey data set in ArcMap using geostatistical analyst. Contour intervals are 100 cm and were generated using spatial analyst surface analyst in ArcMap...?????????????????..???76 Figure 3-7. Comparison of the water depths measured by the Maryland Geological Survey (MGS) and our study. The points compared were positioned less than 20 m apart. The 1:1 line is shown as a solid black line?...?????????...77 Figure 3-8. Frequency distribution of the depth differences observed between the Maryland Geological Survey bathymetric data sets and the data set we collected. The pairs of points compared were positioned within 20 m from each other. The data are normally distributed with a mean of 0.027 m, which given the variability, was deemed to be a non-significant, and thus acceptable, error.?.......................78 Figure 3-9. The subaqueous slope map of Chincoteague Bay was created using the Maryland Geological Survey data set with spatial analyst surface analyst in ArcMap????????????????????????????..80 Figure 3-10. Subaqueous landforms delineated in Chincoteague Bay were hand-digitized using ArcMap. The subaqueous landforms were delineated based on slope, water depth, geographic location, and depositional environment????????...82 Figure 4-1. Locations of full subaqueous soil profile descriptions and brief observations and notes collected in Maryland?s portion of Chincoteague Bay. Locations were selected to determine the composition and variability within landscape units and to identify differences between adjacent units?????????????...95 Figure 4-2. A. Particle-size data for soil horizons that were field textured as sands. B. Particle-size data for soil horizons that were field textured as loamy sands. C. Particle-size data for soil horizons that were field textured as sandy loams. D. Particle-size data for soil horizons that were field textured as loams????..102 Figure 4-3. A. Particle-size data for soil horizons that were field textured as fine sands. B. Particle-size data for soil horizons that were field textured as loamy fine sands. C. Particle-size data for soil horizons that were field textured as fine sandy loams?????????????????????????????103 xi Figure 4-4. A. Particle-size data for soil horizons that were field textured as clay loams. B. Particle-size data for soil horizons that were field textured as clays. C. Particle- size data for soil horizons that were field textured as silty clay loams. D. Particle- size data for soil horizons that were field textured as silty clays??????.104 Figure 4-5. Distribution of particle-size data for 188 subaqueous soil horizons analyzed in this study????????????????????????.???.106 Figure 4-6. Distribution of particle-size data for subaerial soils found throughout Maryland (University of Maryland Pedology Lab, 2007). Each marker represents a different county in Maryland?????????????????.?...107 Figure 4-7. Cumulative frequency curves from sediment samples collected from Barataria Bay, LA, which is a tidal lagoon. These curves represent five different depositional environments found within Barataria Bay (From Krumbein, 1939). The five types of sediments are Type I: beach sands and shallow water sands in the zone of breakers with a median value of ? = 3, Type II: predominately sandy, but with some silt and clay, and occurs in channels where currents are stronger with a median value of ? = 3.3, Type III: composed of 50% sand and occur on the border of channels and cover locally large areas with moderately deep water with a median of ? = 4, Type IV: predominantly silty with an average of 25% sand, located in the basin with a median of ? = 4.7, and Type V: contains the finest sediments with highest organic contents and a median ? = 6; are located along fringe of low islands and in areas farthest from the currents???????...108 Figure 4-8. Cumulative frequency curve from the storm-surge washover fan flat in Chincoteague Bay (pedon CB16). These curves are similar to the Type I and II curves described by Krumbein (1939)????????????????.110 Figure 4-9. Cumulative frequency curve from the barrier cove in Chincoteague Bay (CB52). These curves are similar to the Type II curves described by Krumbein (1939)????????????????????????????...111 Figure 4-10. Cumulative frequency curve from the lagoon bottom in Chincoteague Bay (pedon CB18). These curves are similar to the Type III and IV curves described by Krumbein (1939)???????????????????????.112 Figure 4-11. Cumulative frequency curve from the mainland cove in Chincoteague Bay (pedon CB21). These curves are similar to the Type III and IV described by Krubein (1939)??????????????????????..??...114 Figure 4-12. Cumulative frequency curves from a subaerial soil located in Worcester County, Maryland??????????????????..?????..115 Figure 4-13. A. Distribution of Trask sorting coefficients (1939) for soils in Chincoteague Bay. Excellent sorted ranges from 0 to 0.58, well sorted ranges from 0.58 to 1.32, moderately well sorted ranges from 1.32 to 2.0, and poorly sorted is greater than 2. B. Distribution of Folk sorting coefficients (1974) for soils in Chincoteague Bay. Very well sorted ranges from 0 to 0.35, well sorted ranges from 0.35 to 0.50, moderately well sorted ranges from 0.50 to 0.71, moderately sorted from 0.71 to 1.0, poorly sorted ranges from 1.0 to 2.0, very poorly sorted ranges from 2.0 to 4.0, and extremely poorly sorted is greater than 4.0???????????116 xii Figure 4-14. A. Distribution of Trask sorting coefficients (1939) for soils in Wicomico and Worcester County, Maryland. Excellent sorted ranges from 0 to 0.58, well sorted ranges from 0.58 to 1.32, moderately well sorted ranges from 1.32 to 2.0, and poorly sorted is greater than 2. B. Distribution of Folk sorting coefficients (1974) for soils in Wicomico and Worcester County, Maryland. Very well sorted ranges from 0 to 0.35, well sorted ranges from 0.35 to 0.50, moderately well sorted ranges from 0.50 to 0.71, moderately sorted from 0.71 to 1.0, poorly sorted ranges from 1.0 to 2.0, very poorly sorted ranges from 2.0 to 4.0, and extremely poorly sorted is greater than 4.0. Using both classification systems most of the subaerial soils are poorly sorted compared to subaqueous soils that are better sorted?????????????????????????????117 Figure 4-15. Moist incubation pH data for a sandy textured soil (Core CB01). In all horizons, except the surface, pH drops below 4 within eight weeks????...119 Figure 4-16. Moist incubation pH data for a loamy textured soil profile (Core CB18). None of the horizons showed a drop in pH within eight weeks, but they did begin to drop below 4 within 11 to 15 weeks????????????????120 Figure 4-17. Moist incubation pH data for a loamy textured soil profile that contains biogenic calcium carbonate in several horizons (Core CB141). Note the samples with excess carbonates maintained a pH around 7-8??????????...121 Figure 4-18. Distribution of chromium reducible sulfides (disulfides) with depth of soils on the storm-surge washover fan flat (CB01), lagoon bottom (CB11 and CB58), barrier cove (CB52), and mainland cove (CB11)????????????125 Figure 4-19. The frequency distribution of the calculated n values for 163 samples from Chincoteague Bay. The samples with more than 95% sand were not included because the values were erroneous. ..???????????????..?127 Figure 4-20. The frequency distribution of n values estimated in the field for 163 samples from Chincoteague Bay. Note the sandy textured soils (fs, ls, or lfs) mostly had n values less than 0.7 and the finer textured soils (sicl, sic, or c) had n values greater than 1?????????????????????????????128 Figure 4-21. Comparison of the field estimated n values and the calculated n values for 163 samples collected in Chincoteague Bay. The field estimated n values for the sandier soils (>50% S) did not correlate well with the calculated n values, but the finer textured soils (<50% S) were better correlated. The field estimated n value provided a more accurate description of the fluidity and bearing capacity of the soils?????????????????????????????..130 Figure 4-22. Porewater salinity for soils located on the storm-surge washover fan flats (CB01 and CB56), barrier coves (CB10), and lagoon bottom (CB18 and CB79). The salinity levels generally do not show a trend with depth and do not decrease below 20 ppt. Note the dashed lines represent the salinity range found within Chincoteague Bay????????????????????????131 xiii Figure 4-23. Porewater salinity contents for soils located near the mainland in the mainland cove and lagoon bottom landforms. CB09 is closest to the mainland (120 m) and CB97 is farthest from the mainland (1200 m). Salinity in the near surface horizons approached that of the overlying bay water, but decreases with depth. The decrease in porewater salinity levels with depth was attributed to groundwater influx into the bay. Note the dashed lines represent the salinity range found within Chincoteague Bay??????????????????...133 Figure 4-24. Samples collected from 11 acid non-calcareous subaerial soil samples that were treated with 5% sulfurous acid. The organic carbon contents of the untreated samples and treated samples differed by an average of 7.5% (SD 3.4%). This difference indicated that the sulfurous acid treatment oxidized a portion of the organic carbon?????????????????????????..135 Figure 4-25. Samples collected from non-effervescent subaqueous soils were treated with 5% sulfurous acid. The organic carbon contents of the untreated samples and treated samples differed by an average of 4.5% (SD 3.1%). This difference indicated that the sulfurous acid treatment oxidized a portion of the organic carbon????????????????????????????...136 Figure 4-26. Calcium carbonate distributions of select pedons located on the storm-surge washover fan flat landform. These sandy soils have low quantities of calcium carbonate throughout the profile??????????????????..138 Figure 4-27. Calcium carbonate distributions of select pedons located on the lagoon bottom landform. These finer textured soils have low quantities of calcium carbonate throughout the profile???????????????.???.139 Figure 4-28. Calcium carbonate distributions of select pedons located on the lagoon bottom landform. These finer textured soils have high quantities of calcium carbonate within the upper 100 cm of the profile. The biogenic shells in these horizons were broken and located in bands which indicate that these shells may have been transported to these areas rather than from in situ organisms???.140 Figure 4-29. Organic carbon distributions of select pedons located on the mainland cove and submerged wave-cut headland landforms. Three pedons (CB11, CB21, and CB124) contained buried organic horizons within 100 cm of the soil surface. The remaining pedons (CB26, CB97, and CB136) contained buried organic horizons located deeper than 100 cm below the soil surface???????????..141 Figure 4-30. Organic carbon distributions of select pedons located on the lagoon bottom landform. These pedons display irregular carbon distribution with depth. Pedon CB58 is located on the barrier island side of the lagoon bottom and the upper portion of the soil formed in sandy barrier island sediments and the deeper portion of the soil formed in finer textured lagoon bottom sediments???????.143 Figure 4-31. Organic carbon distributions of select pedons located on the storm-surge washover fan flat landform. These soils are sandy and have lower organic carbon contents than finer textured soils. Pedon CB45 has an irregular increase in organic carbon with depth. The upper portion of this soil formed in sandy barrier island sediments and the lower portion of the soil formed in finer textured sediments???????????????????????????..144 xiv Figure 4-32. X-ray diffraction pattern of the fine silt fraction from sample CB11 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), and ilmenite (Il)??????????.155 Figure 4-33. X-ray diffraction pattern of the fine silt fraction from sample CB18 Cg 8-50 cm and Cg 50-100 cm. The sample is dominated by quartz (Q) and also contains albite (Al), mica (M), kaolinite (K), and ilmenite (Il)??????????.156 Figure 4-34. X-ray diffraction pattern of the fine silt fraction from sample CB58 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), and ilmenite (Il)??????????.157 Figure 4-35. X-ray diffraction pattern of the coarse silt fraction from sample CB58 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), orthoclase (O), and ilmenite (Il)??.158 Figure 4-36. X-ray diffraction pattern of the clay fraction from sample CB11 Cg1. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), cristobalite (Cb), and jarosite (J) minerals???160 Figure 4-37. X-ray diffraction pattern of the clay fraction from sample CB11 Cg2. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), gibbsite (G), quartz (Q), feldspar (F), cristobalite (Cb), and jarosite (J) minerals????????????????????????????161 Figure 4-38. X-ray diffraction pattern of the clay fraction from sample CB18 Cg 8-50 cm. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), orthoclase (O), and cristobalite (Cb) minerals????????????????????????????162 Figure 4-39. X-ray diffraction pattern of the clay fraction from sample CB18 Cg 50-100 cm. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals????163 Figure 4-40. X-ray diffraction pattern of the clay fraction from sample CB58 Cg1. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals???????...164 Figure 4-41. X-ray diffraction pattern of the clay fraction from sample CB58 Cg2. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals???????...165 Figure 4-42. Classification of subaqueous soil profiles in Maryland?s portion of Chincoteague Bay using the proposed changes to Soil Taxonomy?????..172 Figure 4-43. Classification of pedons described in Chincoteague Bay, MD, to the series level?????????????????????????????..179 Figure 5-1. Location map of the subaqueous soil profiles described in Chincoteague Bay and the subaqueous landscape units they occupy????????????202 Figure 5-2. Location of described pedons located along transect 1 from the adjacent tidal marsh into Chincoteague Bay???????????????????..215 Figure 5-3. Location of described pedons located along transect 2 from the adjacent tidal marsh into Chincoteague Bay???????????????????..216 Figure 5-4. Soil profiles described on transect 1. Carbon-14 dates for two buried organic horizons????????????????????????????218 Figure 5-5. Soil profiles described on transect 2. Carbon-14 dates for three buried organic horizons????????????????????????????219 xv Figure 5-6. Surface textures of soil profiles described in Chincoteague Bay????..225 Figure 5-7. Subaqueous soil map of Chincoteague Bay. The legend for this map is given in Table 5-7??????????????????????????..226 Figure 5-8. Location map of described pedons classified to the family level of Soil Taxonomy and the corresponding soil map units????????????229 Figure 5-9. Location map of described pedons classified to the series level of Soil Taxonomy and the corresponding soil map units????????????236 Figure 5-10. Pedons composed of sandy materials and the corresponding map units?235 Figure 5-11. Pedons composed of silty textures throughout (SiCL, SiL, or CL), pedons with coarser textured materials in the substratum, and pedons with a sandy surface horizons and the corresponding map units??????????????...237 Figure 5-12. Location of pedons in Chincoteague Bay that were shallow organic soils (Histosols, Tumagan series), or that contained organic horizons within 100 cm of the soil surface (Thapto-Histic, Southpoint series), or organic horizons deeper than 100 cm (Typic, Truitt series)??????????????????240 Figure 6-1. A conceptual model showing how the attenuation of light as it passes through the estuarine water column that reduces its availability for SAV to support photosynthesis (modified by Batiuk et al., 2000)????????????248 Figure 6-2. Predicted soil suitability for SAV habitat based on soil characteristics including sulfide concentration, texture, and organic carbon content. Soil map units were grouped based upon their degree of limitation (slight, moderate, or severe) for SAV habitats?????????????????????..266 Figure 6-3. Annual seagrass coverage (ha) for Chincoteague Bay from 1986 through 2006 Submerged aquatic vegetation coverage was obtained from the Virginia Institute of Marine Science (VIMS)?????????????????268 Figure 6-4. The SAV distribution and density collected in 1986 by VIMS using rectified photography was obtained during peak SAV growing season. Four density classes were identified based on the percent cover: very sparse (<10% coverage); sparse (10-40% coverage); moderate (40-70% coverage); and dense (>70% coverage)???????????????????????????..269 Figure 6-5. The SAV distribution and density collected in 2004 by VIMS using rectified photography was obtained during peak SAV growing season. Four density classes were identified based on the percent cover: very sparse (<10% coverage); sparse (10-40% coverage); moderate (40-70% coverage); and dense (>70% coverage)???????????????????????????..270 Figure 6-6. The SAV coverage in 2004 and the potential suitability for SAV growth based on soil characteristics of Chincoteague Bay. Note that most of the SAV beds are located adjacent to the barrier island?????????????.272 Figure 6-7. The total hectares of SAV per density class found within each soil suitability unit in Chincoteague Bay, Maryland. Note the highest SAV coverage is found within the slight class??????????????????????...273 Figure 6-8. The percentage of SAV for each density class is shown for each suitability class (each density class adds up to 100%). Note the greatest SAV coverage was located on soils with slight limitations for SAV growth?????????..274 xvi Figure 6-9. Percent of the total area designated within each soil suitability class in Chincoteague Bay that supported SAV growth in 2004 (by density class). Note the highest percentage (35%) by SAV occurred in areas with slight limitations with only 1% coverage in areas with severe limitations?????????..275 Figure 6-10. Location of soil descriptions made during the summers of 2004 and 2005. Twelve soils were described as supporting SAV on the surface or having plant roots within the surface horizons??????????????????.277 1 Chapter 1: Introduction Background According to Bates and Jackson (1987) a lagoon is a ?shallow stretch of salt and brackish water partially or completely separated from a sea or lake by an offshore reef, barrier island, sandbank or spit?. Lagoons have high productivity, are important ecological habitats, and are important economic resources. These environments support many species, including macrophytes, benthic fauna, and aquatic fauna. These areas have been studied within a broad range of disciplinary specialties, where the vegetation (Koch and Beer, 1996), benthic fauna (Fox and Ruppert, 1985), and sediment distributions (Bartberger, 1976; Wells and Conkwright, 1999) have been examined. Until recently these areas have not been studied by soil scientists. In the last decade, the definition of soils has been expanded to include areas that are permanently submerged with deeper water (up to 2.5 m) (Soil Survey Staff, 1999). Subaqueous soils form from permanently submerged sediments located in rivers, lakes, and tidal environments. There have been several studies examining subaqueous soils in subtidal lagoons located in Delaware, Maine, Maryland, and Rhode Island from a pedological perspective (Demas, 1998; Bradley and Stolt; 2003; Osher and Flannagan, 2006). These studies involved characterizing the morphological properties of the soils and describing them using terminology commonly used for subaerial soils. These studies highlight the relationships between subaqueous landforms and soil types (Demas, 1998; 2 Bradley and Stolt; 2003; Osher and Flannagan, 2006). The subaqueous soil-landscape models developed from these studies could potentially be extended to coastal lagoons throughout the Atlantic coast. Study Area There are five coastal lagoons in Maryland that have locally been termed coastal bays: Assawoman Bay, Isle of Wight Bay, Sinepuxent Bay, Newport Bay, and Chincoteague Bay (Figure 1-1). These coastal lagoons are located on the Atlantic coast of the Delmarva Peninsula. Fenwick and Assateague Islands are barrier islands that separate the coastal lagoons from the Atlantic Ocean. Assawoman Bay and Isle of Wight Bay are located north of the Ocean City Inlet. The southern bays consist of Sinepuxent Bay, Newport Bay, and Chincoteague Bay. Newport Bay and Sinepuxent Bay are contiguous with Chincoteague Bay at their southern boundaries and are located between the Ocean City inlet and the Chincoteague inlet. Chincoteague Bay is the largest of the Maryland coastal lagoons. Chincoteague Bay is a 19,000 ha coastal lagoon bounded by Assateague Island to the east and Maryland mainland (Worcester County) to the west. It is connected to the Atlantic Ocean by the Ocean City inlet to the north and the Chincoteague inlet to the south (approximately 52 km apart). The restricted access of water inflows and outflows means that it takes approximately 63 days for 99% of the water in Chincoteague Bay to be replaced by tidal exchange (EPA, 1999). Chincoteague Bay is a microtidal (tidal range < 2 m) lagoon with a very small average daily tidal range of 10-20 cm near Public Landing, MD (Wazniak et al., 2005). Generally the water depths are less than 2.5 m throughout the bay. 3 Figure 1-1. Map of Maryland coastal lagoons. The study area is highlighted. (Modified from Wazniak et al., 2004). 4 Chincoteague Bay is polyhaline, meaning that the salinity changes seasonally within a range of 26 to 34 ppt. The highest salinity values occur in the summer due to higher evaporation rates, poor circulation, and decline in fresh water inputs (Wells and Conkwright, 1999). The Chincoteague Bay watershed is largely undeveloped. The western shore watershed is composed of wetlands (15%), forest and brush (40%), agricultural (33%), and developed land (4%) (Shanks, 2005). Assateague Island to the east was established as a national park (Assateague National Seashore Park) in 1965 and has remained undeveloped since that time. The health of Maryland?s coastal bays was assessed by the Maryland Department of Natural Resources (Wazniak and Hall, 2005) using three different types of indicators: water quality; living resources; and habitat. Chincoteague Bay was ranked second highest after Sinepuxent Bay, due to its relatively undeveloped watershed and its degree of flushing through the Ocean City and Chincoteague Inlet. But due to the prevalence of brown tides and macroalgae blooms its overall ranking was reduced (Wazniak and Hall, 2005). Chincoteague Bay has good/excellent water quality, but the water clarity (measured by Secchi disk) was less than 0.5 m in the summer months (Wazniak and Hall, 2005) due to algal blooms that occur throughout the summer. This is supported by chlorophyll a concentrations (measurement of algal populations), which tend to be less than 15 ?g l -1 (Wazniak and Hall, 2005). The dissolved oxygen concentrations are generally greater than 5.0 mg l -1 , however in the summer months in near-shore areas, the oxygen concentrations are lower, dropping into the range of 5 to 3 mg l -1 . Nutrient inputs into the coastal bays through non-point sources (agriculture, septic systems, and atmospheric deposition) and groundwater were thought to be responsible for the increase 5 of nitrogen and phosphorus into these systems. Average total nitrogen concentrations ranged from 0.04 to 1 mg l -1 and average total phosphorus concentrations ranged from 0.025 to 0.1 mg l -1 in Chincoteague Bay (Wazniak and Hall, 2005), which are lower values that those observed in other coastal lagoons in the Mid-Atlantic area. The sediments of Chincoteague Bay also appear to be relatively pristine according to Wells and Conkwright (1999). The sediments are not enriched in metals (Cd, Cu, Cr, Ni, Pb, or Zn) and nutrients (N or P) due to anthropogenic activities, with levels in the sediments falling within established background levels (Wells and Conkwright, 1999). Brown tides, which are the result of large quantities (>200,000 cell ml -1 ) of the pelagophyte Aureococcus anophagefferens, are detrimental to benthic organisms in Chincoteague Bay by decreasing oxygen concentrations and light. These were observed in Chincoteague Bay between 1999 and 2003 and occurred mainly from May to July and September to early November (Simjouw et al., 2004). Chincoteague Bay supports a variety of fish, benthic flora, and fauna species. Over 130 different fish species have been identified over the last 30 years, including summer flounder, croaker, weakfish, spot, striped bass, and black sea bass (Wazniak and Hall, 2005; Shanks, 2005). Blue crabs are abundant and have maintained a steady population over the last 13 years (Wazniak and Hall, 2005) (in contrast to the Chesapeake Bay, where crab populations have been in serious decline (Miller et al., 2005)). Oysters were once extensive throughout the bay, but have declined drastically during the 20 th century due to harvesting, disease, and predation (Shanks, 2005; Wazniak and Hall, 2005). When surveys in Chincoteague Bay were made during 2000-2004, oysters were found to be absent from subtidal shoals and former oyster bars (Wazniak and Hall, 2005). 6 Bay scallops were prevalent until the 1930?s when eelgrass beds declined due to wasting disease, but have recently (since 2002) been found in all coastal bays. The recent resurgence was attributed to the increase in seagrass coverage over the last twenty years (Wazniak and Hall, 2005). Hard clam populations have been stable over the last 10 years, at an average density of approximately 0.27 clams m -2 , but historically the populations were greater (Wazniak and Hall, 2005). In 1953 the reported clam density was 1.3 clams m -2 (Shanks, 2005). Submerged aquatic vegetation was virtually eliminated from the bays in the 1930?s by disease, but in the last 20 years submerged aquatic vegetation has increased in extent from approximately 2129 ha in 1986 to 3204 ha in 2006. However there has been a reported decline in the seagrass population since 2002 from 6235 to 3204 ha (Maryland Department of Natural Resources, 2007). This decline has been attributed to warmer temperatures and lower water clarity. Most of the submerged aquatic vegetation beds are located on the eastern side of Chincoteague Bay along Assateague Island. In recent years a few submerged aquatic vegetation beds have begun to appear on the western side of the bay as well (Orth et al., 2005). Geologists have examined the sediments of Chincoteague Bay (Bartberger, 1970; Wells and Conkwright, 2004) and ecologists have worked to assess the biologic productivity (Drobeck et al., 1970; Leber and Lippson, 1970; Shanks, 2005) and primary productivity of the lagoon (Anderson, 1970; Orth et al., 2005). This area has not been studied by soil scientists from a pedological perspective, although pedological work has been done in the adjacent but much smaller Sinepuxent Bay, to the north (Demas and Rabenhorst, 1999). Undertaking an effort to study the subaqueous soils of a large coastal lagoon like Chincoteague Bay will allow us to assess, and hopefully enhance the 7 predictive capability of subaqueous soil-landscape models developed in more limited settings and to determine their applicability from a regional perspective. Furthermore, the acquisition of spatial soils information for Chincoteague Bay should provide a valuable resource for use in ecological research and management. Objectives The objectives of this study were: 1) to identify and delineate the subaqueous landforms of Chincoteague Bay, Maryland; 2) to evaluate the suitability of existing subaqueous soil-landscape models of Atlantic coastal lagoons when applied to a broader scale and to modify or enhance those models as needed; 3) to develop a soil map of Chincoteague Bay; and 4) to demonstrate the potential usefulness of subaqueous soils information by assessing the suitability of Chincoteague Bay soils for submerged aquatic vegetation habitat. 8 Chapter 2: Literature Review Barrier Islands and Coastal Lagoons Barrier islands are located along the coasts of every continent, except Antarctica. There are approximately 2200 barrier islands most of which exist in the northern hemisphere (73%) and of these, 405 are in the United States. Most of the barrier islands world-wide are located on wide continental shelves found along the east coasts of the North and South American continents (Pilkey, 2003). Nine types of barrier islands have been described: coastal plain barrier islands; delta barrier islands; Arctic barrier islands; bay mouth barrier islands; sandur barrier islands; composite barrier islands; accidental barrier islands; man-made barrier islands; and lagoon barrier islands (Pilkey, 2003). According to this classification the barrier islands along the Mid-Atlantic coast are coastal barrier islands, because they meet these five basic requirements: rising sea level (transgressive coastline); gently sloping mainland surface; supply of sand; energetic waves; and a low to intermediate tidal range (Pilkey, 2003). Sea levels have moved up and down many times during the last three million years, the most significant of which have been related to glaciation. Each time glacial ice accumulated (generally related to glacial advances) sea level dropped, at times as much as 120 m (Pilkey, 2003). During these times when water formerly contained in oceans became glacial ice, the sea level dropped and sediments on the continental shelf were exposed as the shelf moved seaward. When the last glaciation (Wisconsinan) began 9 approximately 120,000 B.P., sea levels were approximately five to six meters above present (Toscano et al., 1989). But as the glaciers formed by accumulating ice and advanced toward their maximum extent during the late Wisconsinan period (18,000 yr B.P.), the sea level dropped to approximately 100 m below present levels (Biggs, 1970; and Sugarman, 1998). The subsequent retreat of glacial ice and sea level rise at the end of the Pleistocene are thought to have occurred in two major steps with the first beginning 12,500 yr B.P. and ending at 11,000 yr B.P. The sea level at the end of this period was estimated to have been between 26 m (Kraft et al., 1986) and 30 m (Colman et al., 2000) below present levels. A second episode of rapid sea level rise occurred around 9,500 yr B.P. and was followed by slower rates of sea level rise throughout the remainder of Holocene (Faribanks, 1989). Most of the coastal and estuarine features, such as barrier islands and lagoons, formed as a result of the rise in sea level during the last 20,000 years (Biggs, 1970; Toscano et al., 1989). There are three main theories of the origin of barrier islands: 1) spit breaching; 2) beach ridge isolation; and 3) submarine bar up growth. The spit breaching concept proposed in the 1880?s by G.K. Gilbert (Gilbert, 1885) stated that on coastal plains recently flooded by sea level rise, sand spits form across the mouths of bays and lagoons because the waves from the open ocean refract as they came in contact with the bay. The refraction of the waves along the shoreline reduced the energy of the waves and their capacity to carry sand-sized particles. The sand was dropped at the entrance of the bay and spits were formed over time. Figure 2-1 illustrates the formation of a barrier island from a spit through sediments transported by littoral and longshore currents. Over time, as the spits grew and developed, storms would break through the spits and form islands 10 Figure 2-1. Idealized diagram of Gilbert?s Theory of barrier island formation from a spit through sediments transported by littoral and longshore currents. 1 and 2) The spit develops in the direction of longshore sediment transport. 3) The spit is breached to form a barrier island (Modified from Hoyt, 1967). 11 (Gilbert, 1885; Pilkey, 2003). It was generally accepted that barrier islands could develop from spits on limited scales, so long as there was an abundance of sediment available for longshore and littoral transport. Hoyt (1967) proposed the beach ridge isolation theory for barrier island formation, which is a modification of de Beaumont?s theory (Pilkey, 2003). Hoyt theorized that barrier island formation has three components: 1) the sea intersects the mainland along the shoreline, 2) a dune or beach ridge forms adjacent to the shoreline, and 3) submergence (such as during rapid sea level rise of the late Holocene period) floods the area landward of the dune or beach ridge forming lagoons and islands. Over time the islands may shift landward, seaward, or remain stationary. This movement is dependent on sediment supply, the rate of submergence, and hydrodynamic factors. The earliest theory on barrier island formation, however, was the work conducted by de Beaumont in 1845. De Beaumont?s hypothesis stated that wave action on the shallow continental shelf removes sediments and then piles them up to form a bank parallel to the shoreline as the waves lose energy and that the sediment bank eventually develops into a barrier island. This theory was further examined by Otvos (1977) with his work in the Gulf of Mexico. He observed barrier islands as sandbars are built up during high storm surges to maintain equilibrium with the higher sea level. After the storm water levels drops quickly, the sandbar remains intact and above sea level. This barrier island formation theory is most likely restricted to the broad trailing edge continental shelves that normally have low waves. Hayes (1979) described three basic barrier island inlet types which influence the barrier island morphologies: tide-dominated; wave-dominated; and transitional (Hayes, 12 1979). The inlet types are governed by the ratio of wave energy to tidal current, volume of the tidal prism, nature and size of back-barrier area, and time-velocity asymmetry of the tidal currents (Hayes, 1980). Levin (1993) observed changes in tidal prism and sediment supply resulted in sequential changes in inlet morphology in the Mississippi River delta plain. He noted sequential changes in inlet morphology as increased tidal prism caused a wave-dominated inlets to develop tide-dominated morphology and changed back to wave-dominated as sediment supply decreased (Levin, 1993). The tide-dominated inlets are characterized by strong ebb currents influencing sediments seaward of the shore zone and have small or non-existent flood-tidal deltas. These inlets occur along the Georgia and southern South Carolina. The barrier islands in these areas are generally 5 to 15 km long and 1 to 5 km wide. These islands tend to be wide in the central portion and narrow towards the ends (Hubbard et al., 1979). Due to the higher tidal range these islands have extensive marshes behind the barrier island. The inlets are characterized by a deep channel and weakly developed or absent flood-tidal deltas (Hubbard et al., 1979). In wave-dominated inlets sand is pushed through the inlet into the lagoon due to the high wave energy and weak ebb flow in these environments. Figure 2-2 illustrates a wave-dominated inlet setting. Examples of wave-dominated inlets include Assateague Island located on the Delmarva Pennisula and the Outer Banks of North Carolina. The larger waves and low tidal ranges produce barrier islands which are long and thin with only a few tidal inlets and have wide, open lagoons behind the barrier island (Hayes, 1979). The ebb-tidal deltas are small and only extend a short distance from the coast, however, in contrast the flood-tidal delta is large and multilobate occurring behind the 13 Figure 2-2. Illustration of a wave-dominated inlet and the major sedimentary features identified (From Davis, 1994). 14 inlet where the sediment carrying capacity of the flow decreases (Hubbard et al., 1979). The inlets are characterized by a single channel which is shallower than tide-dominated inlets (Hubbard et al., 1979). Inlets associated with these barrier islands are unstable with regard to their location and size, which is caused by high rates of littoral drift, longshore currents, and small tidal prisms. These inlets tend to close over time and new inlets are created during summer hurricanes and winter storms called ?Nor? Easters?. In transitional inlets the waves and tides have equal effects and the majority of the sand occurs in the inlet. These are an intermediate between wave- and tide-dominated inlets which occur along the Virginia, South Carolina, and Louisiana coasts. The inlet morphology is variable in these settings, but the sand deposits are confined to the inlet channel. The inlet is characterized by one main channel and smaller secondary channels (Hubbard et al., 1979). Chincoteague Bay An estuary is ?a semi-enclosed coastal body of water which has free connection with the open sea within which sea water is measurably diluted with fresh water derived from land drainage? (Pritchard, 1967). Estuaries are mostly embayments in the coast with a barrier island that may be a spit or a bar, but is usually detached from the mainland. Estuaries accumulate sediments from streams carrying detrital sediments, tidal currents, and from biogenic materials produced in the estuary. The Chesapeake Bay is one of the largest estuaries in the United States. Lagoons differ from estuaries by the paucity of sediments supplied to the lagoons due to low runoff and limited inlets. The small quantity of fresh water inputs into these coastal lagoons elevates the salinity levels which impacts the benthic communities that inhabit the lagoons. Sediments are received into the lagoon 15 mainly by washover and aeolian process on the adjacent barrier islands. The lagoons generally have hypersaline conditions and support a benthic community tolerant of these conditions. Chincoteague Bay is an example of a coastal lagoon. The formation of Assateague Island and Chincoteague Bay started with sea level rise about 18,000 years ago at the end of the Wisconsinan glacial maximum period, due to the melting and receding of glaciers (Biggs, 1970). Around 13,500 years BP, sea level was approximately 100 m below present levels and the coast was roughly 97 km east of its present location (Pielou, 1991). The present continental shelf was composed of fresh water ponds, grasslands, and spruce forests (Emery, 1967). The sea level continued to rise and by 9,600 years BP the portion of the continental shelf now occupied by Chincoteague Bay had become an estuary, as evidenced by the presence of oyster shells in the sediments (Emery, 1967). The presence of oyster shells in the sediment supports that oysters were living in the lagoon at this time and there may have been a barrier island seaward of this position (Biggs, 1970). A series of barrier islands were present after 5,000 years BP creating Chincoteague Bay. This is evidenced by dating salt marsh peat located at depths of 7 to 8.5 m below MSL being dated by 14 C at approximately 4,500 years BP, indicating that barrier islands existed seaward of the Delmarva for at least the past 4,500- 5,000 years (Biggs, 1970). Biggs (1970) hypothesized that the current Assateague Island formed by the coalescence of several islands over time. Halsey (1978) suggested that Assateague Island formed during the late Holocene when Pirates Island, Pope Island, and the shoals seaward of Morris Island and Cape Chincoteague coalesced and what is now Assateague Island consisted of at least two islands until the Green Run inlet closed around 1900. 16 Chincoteague Bay, the largest of Maryland?s inland coastal bays (Figure 2-3), is a 19,000 ha coastal lagoon bounded by Assateague Island to the east and Maryland mainland to the west. It is connected to the Atlantic Ocean by the Ocean City inlet to the north and the Chincoteague inlet to the south (approximately 52 km apart). Chincoteague Bay is a microtidal (tidal range < 2 m) lagoon with an average daily tidal range of 10-20 cm near Public Landing, MD. Generally the water depths are less than 2.5 m throughout the bay. The restricted access of water inflows and outflows results in a flushing rate of 63 days for 99% of the water in Chincoteague Bay to be replaced by tidal exchange (Pritchard, 1961).Salinity within Chincoteague Bay changes seasonally, from 26 to 34 ppt. The highest salinity values occur in the summer due to high evaporation rates, poor circulation, and decrease in fresh water inputs (Wells and Conkwright, 1999). Bartberger (1976) studied the sediment sources and sedimentation rates in Chincoteague Bay. Chincoteague Bay receives approximately 90,000 m 3 of sediment annually, with an average sedimentation rate of 0.03 cm yr -1 . There are four sources contributing detrital sediment to Chincoteague Bay: 1) from the mainland through streams; 2) from shoreline erosion; 3) from Assateague Island by eolian transport and overwash events; and 4) through the two inlets (Ocean City and Chincoteague). The erosion of the mainland shore and inflowing streams provided most of the finer textured sediments to the bay, whereas the overwash events and eolian transport provided the coarser sediments. It has been estimated that most of the finer textured sediments come from shoreline erosion of the mainland (40 km 3 ) with less from streams (5 km 3 ) (Bartberger, 1976). Two-thirds of the coarse sediments are derived from Assateague Island by overwash events (30 km 3 ) and one-third by eolian transport (15 km 3 ) 17 (Bartberger, 1976). The sediments contributed through the tidal inlets only impact the areas immediately adjacent to the inlet. The ratio of finer textured materials to coarser textured materials (sand:mud) entering the bay is 1:1 (Bartberger, 1976). Bartberger?s (1976) work provided an estimate of the present annual sedimentation rate of 0.03 cm yr -1 . This is significantly lower than the long term average of 0.15 cm yr -1 over the past 5,000 years that was estimated based on sediment thickness recorded in borings (Bartberger, 1976). Sedimentation rates for three cores collected in Chincoteague Bay during the late 1990?s using 210 Pb ranged from 0.17 to 0.33 cm yr -1 (Wells and Conkwright, 1999). These rates were more similar to the long term average estimated by Bartberger (1976), who suggested that the change in sedimentation rates could be related to the present lack of tidal inlets along Assateague Island. Bartberger (1976) suggested that this is an unusual situation and is not what was typical over the last 5,000 years. From historical maps there is evidence that several inlets have opened and closed over the past 200 years. With the closing of the inlets the only supply of sediment from the eastern shore of the bay is through overwash events and eolian transport. There are three significant marsh areas in Chincoteague Bay (Johnson Bay area, Middlemoor area, and Tingles Island area) as shown in Figure 2-3. The marshes located in Johnson Bay (especially Mills Island) are associated with dune deposits and are aligned with Sinepuxent Neck and Robins Marsh, and both are part of Pleistocene beach ridges (Rasmussen and Slaughter, 1955). Thus, many of the islands in Johnson Bay area are believed to be late Pleistocene in age rather than Holocene (Wells and Conkwright, 18 Figure 2-3. Map of Chincoteague Bay, Maryland showing three major areas of marshes (Modified from Biggs, 1970). 19 1999). The Middlemoor and Tingles Island marshes are associated with relict inlets. The Middlemoor marshes are associated with the Green Run inlet, which was open in 1850 and closed 1900 (Figure 2-4). These inlets were located at the ?right? position to have supplied sediment and tidal range to stimulate marsh development (Bartberger and Biggs, 1970). Tingles Island marshes are associated with the now closed North Beach inlet. Biggs (1970) hypothesized that the Middlemoor and Tingles Island marshes are retrograding because the inlets associated with their formation have closed, thus decreasing the source of sediment to create new shoals for marsh encroachment. Several relict inlets have been documented along Assateague Island as shown in Figure 2-5. These inlets formed during storms and eventually filled in with sediments. These relict inlets helped to shape Assateague Island and had an important role on the distribution and character of the bay bottom sediments. However, today there are only two inlets. The Ocean City Inlet formed in 1933 during an August hurricane. The inlet was stabilized by jetties in 1935 by the Army Corps of Engineers (Shepard and Wanless, 1971). Due to a strong littoral current that flows southward, the north jetty trapped sand and formed a triangular shaped beach, while starving Assateague Island south of the inlet. This caused the northern portion of Assateague Island to recede about 1,500 feet and by 1961 the beach was no longer connected to the jetty. In 1963, dredging operations reconnected the jetty and beach. The Chincoteague inlet is located in the southern portion of Assateague Island and Chincoteague Island (Figure 2-3). Sediment Mapping in the Coastal Bays Biggs (1970) examined the sediments underlying Chincoteague Bay and Assateague Island by collecting 26 cores on six transects (Figure 2-6). Salt marsh peat 20 Figure 2-4. Historical record of the development of Middlemoor and the closing of Green Run Inlet (From Gawne, 1966). 21 ? Figure 2-5. Locations of prior inlets once open, but now closed located on Assateague Island, Maryland (From Wells and Conkwright, 1999). 22 Figure 2-6. Locations of borings from Biggs (1970). 23 was identified in several of the cores, which marks the approximate sea level at the time the peat accumulated. The presence of salt marsh peat at 7 to 8.5 m below present MSL and the accompanying 14 C dates provide an approximate age of 4,500 to 5,000 years BP for these marsh surfaces. The marsh deposits at the surface of the cores were thin (< 0.5 m) and indicated that prior to marsh development these areas of the lagoon were open water (Biggs, 1970). Daddario (1963) dated basal peat (1,900 years BP) in the lagoon west of Atlantic City, New Jersey found at a depth of 3 m below MSL. Newman and Munsart (1968) found Wachapreague marshes (in Virginia) were only 1 m thick indicating that marsh formation began approximately 1,000 years BP. They suggested that the marsh formation was inhibited by a rapid rise in relative sea level prior to this. Biggs (1970) data collected from Assateague Island is consistent with these findings, indicating that marsh formation began approximately 1000 years BP as sea level rise slowed allowing marsh vegetation to grow. A map showing the sand content (2 to 0.625 mm) of Chincoteague Bay surface sediments is shown in Figure 2-7 and was based on 147 surficial sediment samples (Bartberger, 1976). The eastern portion of the bay, adjacent to Assateague Island, contains sediments composed of >80% sand (0.125 to 0.250 mm in diameter) (Bartberger, 1976). As water depth increased (from 1.5 m to 2.5 m) from the barrier toward the mainland, there was a decrease in sand content and an increase in finer sediments (average particle diameter of 0.008 mm) (Bartberger, 1976). These finer sediments in water deeper than 1.5 m contain less than 20% sand (Bartberger and Biggs, 1970). The map shows a pocket of finer grained sediments that extends from the middle of the bay to Assateague Island that corresponds to Green Run Bay. This is the site of the 24 Figure 2-7. Percent of sand in surficial sediments of Chincoteague Bay in 1976 (Modified from Bartberger, 1976). The location of a relict inlet, Green Run Inlet, is identified. 25 former inlet, which a channel into the lagoon scoured to a depth of approximately 2.4 m (Bartberger and Biggs, 1970). During the 1990?s the Maryland Geological Survey (Wells and Conkwright, 1999) conducted a sampling project to collect surficial sediments of Chincoteague Bay, MD. The sampling was conducted on a 500 m by 500 m grid, and the samples were colleted using a grab type sampler (an approximate sample area of was 19 cm 2 by 14 cm). The sample descriptions included a brief narrative that described the texture (Shepard?s sediment classification) and fauna of the location. Data collected for each sample included percent water, percent gravel, percent sand (2.0-0.63 mm), percent silt (0.63- 0.004 mm), percent clay (<0.004 mm), total nitrogen, total carbon, and percent sulfur. An additional 12 (1 m deep) sediment cores were also collected throughout Chincoteague Bay. The cores were x-rayed, photographed, described, and sampled at specific locations based on visual and radiographic observations. X-ray radiographs showed such features as worm channels and sedimentary stratification in the profile. Similar data as those collected for the surface grab samples were also collected from the sediment cores and additional metal data were collected (chromium, copper, iron, manganese, nickel, and zinc). A sediment distribution map shown in Figure 2-8 based on Shepard?s Classification scheme (Shepard, 1954) was developed using 988 surficial samples. Sandy (2-0.625 mm) sediments (<25% silt and clay) cover 45% of the bay and were located primarily along Assateague Island (Wells and Conkwright, 1999). The source of the sand-sized particles is thought to be the adjacent barrier island with the sands being transported by eolian or washover events. In the northern half of Chincoteague Bay the sandy sediments extend farther across the bay. These sediments were deposited on the 26 paleo-flood tidal delta that formed when the Sinepuxent inlet was open (Figure 2-5). Another large expanse of sand-sized sediments is located between Middlemoor and Johnson Bay. These deposits were deposited on a paleo-flood tidal delta that formed when the Green Run Inlet was open during the end of the 19 th century (Wells and Conkwright, 1999). Clayey silts cover 26% of the bay bottom (Figure 2-8) and are located along the western shore of the bay from Public Landing to Johnson Bay (Wells and Conkwright, 1999). The sources of these fine grained sediments likely include surface run-off and shoreline erosion. The finer grained sediments were deposited in areas of low-energy where the wave action is at a minimum. There are also pockets of fine grained sediments south of Tingles Island that they attribute to the presence of extensive submerged aquatic vegetation beds which trapped the finer sediments by slowing the currents allowing the finer particles to settle out of the water column (Wells and Conkwright, 1999). Generally the sediments from east to west grade from sandy sediments to clayey silts, with transitional textures occurring in the transitional zones between the high-energy and low-energy environments. A distribution of the sand content from the Wells and Conkwright (1999) data set is shown in Figure 2-9. Limitations of Previous Approaches Many sediment maps are based upon data collected from regularly spaced grid patterns (Wells et al., 1994). Wilding and Drees (1983) have suggested that grid sampling should be utilized when spatial relationships among soil properties are not understood, based upon the underlying assumption that variability is more random than systematic or simply cannot be predicted from any other properties or features (Wilding and Drees, 1983). The continued use of grid pattern sampling may have limited the development and 27 Figure 2-8. Distribution of sediment type of surficial sediments of Chincoteague Bay based on Shepard?s classification scheme (Modified from Wells and Conkwright, 1999). The particle-size classes are: sand (2.0-0.63 mm); silt (0.63 to 0.004 mm); and clay (<0.004 mm). 28 Figure 2-9. Percent of sand (>0.63 mm) in surficial sediments of Chincoteague Bay collected by Wells and Conkwright (1999). This map was created using the Maryland Geological Survey data set in ArcMap using the geostatistical analyst. 29 understanding of sediment spatial relationships (Demas and Rabenhorst, 2001). The sediments are often only sampled to a depth of 30 cm or less. Sampling at a fixed depth often has the effect of mixing together surface and subsurface horizons. Using this approach, maps that have been developed to date represent single parameters, such as grain size distribution. A number of these studies sometimes have included the collection of a few sediment cores (depths ranging from 1 to 10 m or more) from the central portions of lagoons or at equidistant locations along transects. The cores are then often described based on regularly spaced intervals. There are several different geological sediment classifications that tend to use broad classes to describe the sediment, such as mud, silty sand (Flemming, 2000), and sand-silt-clay (Shepard, 1954). This may cause problems when trying to compare sediments that were described using different classification schemes due to the lack of consistency in the terminology. An alternative strategy using a pedologic approach to study shallow water substrates was first applied by Demas (1996) in Sinepuxent Bay, MD. With this approach the shallow water substrates are considered soils and are studied as a three-dimensional collection of horizons that are linked across the landscape (Demas and Rabenhorst, 1999; Bradley and Stolt, 2001). These studies are based on the underlying assumption that the soils vary systematically across landscape units. Therefore, the soils are characterized based upon their physical and chemical properties as a function of depth, instead of as single surface parameters. By studying these areas as soils, a hierarchical taxonomic classification system can be utilized that provides more detailed information. For example, rather than classifying surficial sediment simply as a mud, one might better describe the entire pedon using the soil classification system, as a fine-silty, Typic 30 Sulfaquent. This classification provides information regarding the texture (18-35% clay), the presence of sulfidic materials in the profile, and the low bearing capacity of the soil. And if this soil were classified as a particular soil series, even more useful information can be included. This additional knowledge about the physical and chemical properties of the soils can be utilized in making decisions about the use and management of these estuaries and coastal lagoons. Subaqueous Soils Sediments are ?solid bits and pieces of materials (fragments of rocks and minerals) produced by weathering, transported by various agents like wind, ice, running water, and mass movement, either deposited or precipitated in layers on, at, or near the Earth?s surface normally as loose, unconsolidated material? (Prothero and Schwab, 2004). Sediments deposited in water bodies have been described and mapped according to sedimentary geological terms. There have been several suggestions over the last 150 years that these subaqueous sediments be considered within the realm of soil science (v. Post, 1862; Kubiena, 1953; Muckenhausen, 1965; Ponnamperuma, 1972). According to Hansen (1959), in the 1860?s v. Post (1862) developed a nomenclature for subaqueous soils where he introduced the terms ?gyttja? and ?dy? to describe limnic sediments. Gyttja soil was a ?coprogenic formation consisting of a mixture of fragments from plants, numerous frustules from diatoms, grains of quartz and mica, siliceous spicules from Spongilla, and exoskeletons from insects and crustaceans? (Hansen, 1959). Dy soils consisted of the same constituents as gyttja, but in addition had ?brown humus particles? (Hansen, 1959). These gyttja and dy soil materials differed in the amount of organic materials they contained with gyttja being organic rich and dy being organic poor. 31 Kubiena (1953) proposed a soil classification system for Europe that included sub- aqueous soils. His classification system was comprehensive and included all soils ?including the neglected sub-aqueous soils? to facilitate a better understanding of soil formation processes. Kubiena (1953) separated the sub-aqueous soils into two main categories: 1) young soils always covered with water that do not form peat (our subaqueous soils); and 2) young sub-aqueous soils with peat formation (what would mostly be Histosols in emergent wetlands, bogs, or forests). Kubiena?s sub-aqueous soils classification system is presented in Table 2-1. The terms developed by Kubiena are not currently used in Soil Taxonomy or the World Reference Base. Therefore it is a difficult system to use in describing subaqueous soils. Kubiena also introduced horizonation of the sub-aqueous soil profiles. For example, (A)C, AC, and AG soils described soils that do not have a distinct humus layer (an A horizon), those that do have a distinct humus layer, and those with a humus layer underlain by a gleyed horizon, respectively. Although Kubiena was the first to develop a classification system for subaqueous soils, there is no evidence that this classification system is currently in use anywhere. Muckenhausen (1965) proposed a soil classification system for the Republic of Germany based on Kubiena?s (1953) work. He classified these soils as Subhydric soils and described four types of soils (Table 2-2). Ponnamperuma (1972) also thought that use of the term soil was justified for the uppermost layers of unconsolidated aqueous sediments found in rivers, lakes, and oceans for the following reasons: 1) they were formed from soil components; 2) soil forming processes were occurring; 3) they contained organic matter and living organisms; 4) the bacteria occurring there were similar to those found in 32 Table 2-1. Classification of Sub-Aqueous soils in Kubiena?s Soils of Europe (Modified from Kubiena, 1953). Sub-Aqueous Soils not Forming Peat Interpretation of the Soil I Protopedon Sediments without organic material accumulation Chalk deficient Protopedon Dystrophic lake iron Protopedon Lake Marl Protopedon Sea Chalk Protopedon II Dy Muds low in organic matter and nutrients III Gyttja Organic rich muds, high in nutrients Limnic Gyttja 1. Eutrophic Gyttja 2. Chalk Gyttja 3. Oligotrophic Gyttja 4. Dygttja Lake (fresh water) sediments Marine Gyttja 1. Schlickwatt Gyttja 2. Sandwatt Gyttja 3. Cyanophyceae Gyttja Marine (saline water) sediments IV Sapropel Dark colored sediments rich in organic matter Limnic Sapropel Lake (fresh water) sediments Marine Sapropel 1. Mudwatt Sapropel 2. Diatomwatt Sapropel Marine (saline water) sediments Peat Forming Sub-Aqueous Soils V Fen Emergent wetlands, bogs, Turf-Fen (Turf Peat Moor) 1. Phragmites-Fen (Reed Peat Moor) 2. Carex-Fen (Sedge Peat Moor) 3. Hypnum-Fen (Hypnum Peat Moor) and forests Wood-Fen (Swamp Wood Peat Moor) 33 Table 2-2. Classification of Subhydric Soils in the Federal Republic of Germany Soil Categories (Modified from Muckenhausen, 1965). The types of subhydric soils are based on Kubiena?s (1953) classification of sub-aqueous soils. Class Types Subhydric soils I Protopedon II Gyttja III Sapropel IV Dy 34 terrestrial soils; 5) horizonation was present; and 6) there were differences in texture, mineralogy, and organic matter content. In the first edition of Soil Taxonomy (Soil Survey Staff, 1975) soils were defined as ?the collection of natural bodies on the earth?s surface, in places modified or even made by man of earthly materials, containing living matter and capable of supporting plants out-of-doors?. For the most part subaqueous sediments were excluded by this definition, due to the primary requirement that they be able to support rooted plants. Another issue was related to defining the boundaries of soils. The first edition of Soil Taxonomy (1975) stated that the upper limit of the soils was ?air or shallow water. At its margins it grades into deep water or to barren areas of rock or ice? (Soil Survey Staff, 1975). Therefore, these sediments were further excluded due to their permanent saturation beneath ?deep? water. The definition of soils was changed in the second edition of Soil Taxonomy (1999) to accommodate among others, the recent research examining subaqueous materials as soils by Demas (1998). Even though much of his work was published at or after 1999, the work was done prior to this, and in fact, was to a large degree what led to the change in the definition. The change in the definition did inspire others to follow his lead ? including Stolt, Bradley, Coppock, Osher etc (Personal communication with Rabenhorst, 2007). The new definition included materials as soils that either demonstrated the formation of soil horizons OR those materials that were capable of supporting growth of higher rooted plants. In addition the boundaries of soil were expanded so that the upper limit of soils became ??soil and air, shallow water, live plants, or plant materials that have not begun to decompose. Areas are not considered to 35 have soil if the surface is permanently covered by water too deep (typically greater than 2.5 m) for the growth of rooted plants. Soil?s horizontal boundaries are where it grades into deep water, barren areas, rock, or ice? (Soil Survey Staff, 2006). These changes allowed for subaqueous environments to be studied as soils, owing to the presence pedogenic horizons, regardless of whether plants are growing there. Nine years ago, the World Reference Base (International Society of Soil Science, 1998) defined soil cover as ?a continuous natural body which has three spatial and one temporal dimension?. The soil cover had three main features: 1) they were formed by mineral and organic components that include solid, liquid, and gas phases; 2) the components were organized into structures; and 3) soils were undergoing constant evolution. The international definition of soils has also changed over time to accommodate any object forming part of the Earth?s surface. In 2006, the World Reference Base (International Union of Soil Science Working Group WRB, 2006) defined soils as ?any material within 2 m from the Earth?s surface that is in contact with the atmosphere, with the exclusion of living organisms, areas with continuous ice not covered by other material, and water bodies deeper than 2 m. This new definition includes areas of continuous rock, paved urban soils, soils of industrial areas, cave soils, and subaqueous soils (at least in water shallower than 2 m). The change in the USDA?s definition of soils as well as that of the International society (WRB) has included environments that are permanently submerged. Therefore, soil scientists have begun to study the sediments of shallow subtidal lagoons and bays and to describe them as soils. 36 Pedogenic Paradigm Extended to Subaqueous Environments Demas and Rabenhorst (1999) demonstrated that soil horizons were recognizable and had formed in shallow water substrates due to pedologic processes, and therefore shallow water substrates should be considered subaqueous soils and could be accommodated under a pedologic paradigm. This work resulted in the change in the definition of soils in the second edition of Soil Taxonomy (1999). Simonson?s generalized theory of soil formation and Jenny?s state factor equation for soil formation have been used to develop an understanding of subaqueous soil development processes. Simonson (1959) proposed that soil genesis be considered as two overlapping steps: 1) accumulation of parent materials and 2) differentiation of horizons in the profile. He attributed horizon differentiation to be the result of the processes of additions, losses, transfers, and transformations. Therefore, following this model of Simonson, to conclude that estuarine sediments are actually soils, it is not sufficient merely that sediments support the growth of higher plants, as required in Soil Taxonomy (1999) but it must also be demonstrated that pedogenic processes in these systems are resulting in the formation and development of soil horizons. Demas and Rabenhorst (1999) found evidence of pedogenic processes (additions, losses, transfers, and transformations) active in shallow water sediments leading to the formation of soil horizons. Pedogenic additions in subaqueous soils include the accumulation of shells, vegetative debris, and organic matter, leading to the formation of A horizons in the sediments. In subaqueous systems transfers or translocations of materials into and through the sediments occur through processes of diffusion and bioturbation. An example of this is the movement of oxygen from the overlying water column into the upper 37 portion (centimeters) of the soil profile both by diffusion and bioturbation caused by benthic fauna. This results in a thin oxidized horizon at the surface. Examples of pedogenic transformations in subaqueous soils included the formation of solid phase sulfide minerals by the process of sulfidization and also the microbial decomposition of organic residues. The combination of these processes that are acting in the shallow water sediments of Sinepuxent Bay led to the development of identifiable pedogenic soil horizons and therefore, these systems were understood to be subaqueous soils (Demas and Rabenhorst, 1999). Jenny (1941) developed the state factor equation to explain the genesis and distribution of subaerial soils: S = f (C, O, R, P, T, ?). Based on his work, soils were seen as a product of five interacting factors ? climate, organisms, relief, parent material, and time. In this equation climate (C) included the temperature and precipitation conditions under which the soils form. The organisms (O) factor represented the role of plants, animals, and microbes impacting the soil formation processes. The relief (R) term reflected the influence of topography or location on the formation of soils across a landscape. The parent material (P) factor included the nature, mineralogy, and origin of the geological material from which the soils form. The time (T) term reflected the length of time the other factors have been influencing soil formation, or the age of the soil. The ?dot? factor was a later edition to the model that allowed for additional yet unspecified factors that impact the formation of soils. In 1972, Folger described the primary factors affecting estuarine sediment composition and distribution. Folger?s model is abbreviated using the following equation: Se = f (G, H, B) and describes sediment accumulation as a function of three factors, 38 geology (G), hydrology (H), and bathymetry (B). Geology (G) represents the physical and mineralogical properties of the geologic material from which the sediments were derived. Hydrology (H) included such components as the rate of fresh water influx, salinity, tidal range, and current velocities. Bathymetry (B) refers to the depth of water within the estuary which affects such things as energy of transport, wave action, etc. State Factors of Subaqueous Soil Formation Jenny?s factors of terrestrial soil formation and Folger?s factors for estuarine sediment composition and distribution were integrated and enhanced to develop a state factor model for the formation of subaqueous soils shown in Figure 2-10 (Demas and Rabenhorst 2001). The climatic regime (C) in subaqueous soils primarily includes regional temperature effects. Temperature has direct impact on the rate of chemical reactions in the soil and has the indirect affect of impacting the fauna and flora that are present. Organisms (O) that impact subaqueous soil formation include macroflora, macrofauna, and microbes. The macroflora, such as submerged aquatic vegetation or macroalgae, add organic matter to the soil through growth and subsequent decomposition. This of course also provides an energy source for microbes to facilitate other biogeochemical processes, such as nutrient cycling. The subsurface plant activity can also modify the soil chemistry. For example, seagrasses release oxygen into the sediments which oxidize compounds such as reduced iron and sulfides (Holmer et al., 2005). Macroflora can physically stabilize the surface by protecting the soil against erosion by slowing water currents at the soil surface. Their effectiveness at doing so, however, is dependent on the density of the plants. Low population densities of some plants can be destabilizing due to erosion around the base of individual plants (Koch, 39 Figure 2-10. Synthesis of Jenny?s Factors of Soil Formation and Folger?s factors of estuarine sediment composition and distribution were used to create the Factors of Subaqueous Soil Formation. Jenny?s factors of soil formation included climate (C), organisms (O), relief (R), parent material (P), time (T), and dot factor ( . ). Folger?s factor of estuarine sediment composition and distribution included geology (G), hydrology (H), and bathymetry (B). The factors of subaqueous soil formation included climate (C), organisms (O), bathymetry (B), flow regime (F), parent material (P), time (T), water column attributes (W), and catastrophic events (E). 40 2001). The macrofauna, such as clams and worms as well as epibenthic forms such as crabs, can cause mixing of the surface horizons, which aids in the oxidation of the upper portion of the soil by incorporating oxygenated water. The bathymetry factor (B) includes the depth of water and also the relief. The slope of the landscape in most subaqueous soil systems is very subtle. Furthermore, the topography is difficult to observe due to the overlying water. Nevertheless, a study of subaqueous topography may permit the recognition of distinctive subaqueous landforms. The flow regime (F) includes the speed, direction, and fluctuation of the moving water. These parameters are in turn related to location in the estuary, distance to the inlet, the magnitude of tidal activity, and the bathymetry. The parent material (P) refers to the geologic source materials from which or in which the soils are found and includes such properties as sediment mineralogy of the soils and particle size distribution. Time (T) refers to the length of time that the pedogenic processes have been active, or the age of the soil. Subaqueous soils in estuarine systems are generally young (late Holocene age) but can vary in age. Some of the late Holocene age soils may overlie, buried, or truncated soils that are older (late Pleistocene or even older). The water column attributes (W) are related to the chemistry of the water, such as salinity, alkalinity, percent oxygen saturation, and sulfate content. These parameters affect the flocculation of particles, oxidation rates, and the propensity to form of hydrogen sulfide gas, which can be toxic to some benthic species and which is involved in the formation of sulfide minerals. Catastrophic events (E) refer to such episodes as hurricanes and northeastern storms which can potentially impact the stability of the landscapes and in some cases cause significant erosion or deposition. This state 41 factor equation allows for the development of conceptual models that aid in the understanding of the genesis and distribution of subaqueous soils within an estuary. Research on Subaqueous Soils The pedologic paradigm refers to the use of landforms as a tool to predict how the soils change across the landscape (Hudson, 1999). The components of the soil landscape paradigm can be described in the following statements: 1) the factors of soil formation interact and as a result soils within the same region develop the same soil; 2) the more similar two landscape units are the more similar the soils are; 3) adjacent areas have a predictable spatial relationship; and 4) once the soil-landscape relationship has been identified it can be used to predict soil cover in other areas by determining the characteristic soil-landscape unit. (Hudson, 1992). The soil-landscape paradigm can be considered a synthesis of soil forming factors and landscape position (Hudson, 1992). By using the soil-landscape paradigm soils are studied as pedons, (natural three-dimensional entities) which are linked across the landscape. Soil pedons are studied and characterized by observing a combination of properties that are found in each pedon (which include multiple soil horizons) instead of focusing on a single property (and only in a single, usually surface, horizon). The collection of soil properties are synthesized and used to aid in the mapping of soil units. The landscapes are delineated into units that have similar soil properties and characteristics within a specific region. The use of the association of certain soils with certain landforms aids in the identification of soils across a landscape. In estuaries and coastal lagoons, direct observation of landscape units covered by water greater than one meter is nearly impossible due to the obscuring effects of the overlying water. However, 42 shallow water landforms (generally in water <1 m in depth) are identifiable on high resolution infrared photographs. Using high quality bathymetric digital elevation models (DEMs) landscape units can be delineated based on water depth, slope, landscape shape, depositional environment, proximity to fresh water, and geographical setting. Relationships between subaqueous landscapes and associated soils have already been documented in previous studies by Demas (1998) in Sinepuxent Bay, MD, Bradley and Stolt (2003) in Ninigret Pond, RI, and Osher and Flannagan (2006) in Taunton Bay, ME. Thus, the association of certain soils with certain landforms (or what is called a soil- landscape model) that have been developed within each of these settings, can be used to predict where the various soils occur on similar landscapes nearby. A first attempt at obtaining soils information can be obtained for a particular area by collecting geomorphic maps, high quality aerial photography, and established soil- landscape models for the region. A preconceived notion of what types of soils to expect is based upon established soil-landscape models. This is the fundamental principle of the pedologic paradigm (Hudson, 1990). Initially soil boundaries are based on landforms (geomorphic maps). These boundaries are checked by collecting information on the soils across the landforms and boundaries to confirm the soil properties and systematic changes (Schaetzl and Anderson, 2005). This process leads to confirming the lines, adding new lines, or aggregating landforms together. In subaerial settings, changes in topography (slope curvature, steepness, or aspect) affect which soils can exist at a site and soils can be identified on terrain alone (Moore et al., 1993). In subaqueous settings the slope is very subtle and is not as useful in identification of landforms and soils. 43 However, water depth and depositional environments are more useful in the identification of particular soils. Demas (1998) created the first subaqueous soil investigation in the USA in Worcester County, Maryland. The study area was a 1300 ha portion of Sinepuxent Bay. Sinepuxent Bay has an average daily tidal range of less than 0.5 to 0.75 m and water depths less than 4.5 m and is connected to the Atlantic Ocean through Ocean City inlet. In this work, Demas identified seven distinct subaqueous landforms based on slope gradients, concavity, and convexity, and water depths (actual elevation), to which he applied the following names: mid-bay shoal; overwash fans; barrier island flats; shallow mainland coves; deep mainland coves; transition zones; and central basin. From 85 soil profile descriptions and associated characterization data, Demas identified six soil series that were associated with the seven major landforms described in Sinepuxent Bay, concluding that subaqueous soil properties are a function of the landform. He observed that bathymetry, flow regime, and geomorphic setting had the greatest impact on the properties and classification of the subaqueous soils on the various landforms. The major soils associated with the landforms identified in Sinepuxent Bay are shown in Table 2-3. Bradley and Stolt (2003) conducted a soil investigation in a 116 ha portion of Ninigret Pond, Rhode Island. Ninigret Pond was a shallow, microtidal (average daily tidal range of 7 to 16 cm) estuary open to the Atlantic Ocean through Block Island Sound. Bradley and Stolt delineated 12 subaqueous landforms based on water depth, slope, landscape shape, and depositional environment. In naming the landforms they 44 Table 2-3. Landforms and the associated soils found in Sinepuxent Bay, Maryland (Modified from Demas, 1999). Landform Name Classification (Soil Taxonomy) Series Diagnostic Soil Properties Used in Series Differentia Mid-Bay Shoal Coarse-loamy, Typic Sulfaquents Sinepuxent 1. Sulfidic materials 2. Fluid (n value >0.7) 3. Multiple lithologic discontinuities Overwash Fans Typic Psammaquents Fenwick 1. Sandy soils 2. Non-fluid (n value <0.7) 3. Low organic C content Barrier Island Flats Coarse-loamy, Sulfic Fluvaquents Tizzard 1. Sulfidic materials 2. Irregular Organic C distribution Shallow Mainland Coves Typic Psammaquents Newport 1. Sandy soils 2. Chroma 3 or greater in subsoil Deep Mainland Coves Fine-silty, Typic Sulfaquents South Point 1. Finer textured 2. Fluid (n value > 0.7) 3. Buried organic horizons within upper 1m 4. Sulfidic materials 5. Highest organic C contents Transition Zones Typic Psammaquents Wallops Central Basin Fine-silty, Typic Sulfaquents No Series Available 45 observed, they tried as much as possible to use terms already in use in the geological and geographical literature. The 12 landforms identified in Ninigret Pond were named lagoon bottom, storm-surge washover fan flat, flood-tidal delta flat, storm-surge washover fan slope, flood-tidal delta slope, barrier cove, mainland submerged beach, mainland cove, mainland shallow cove, mid-lagoon channel, barrier submerged beach, and shoal. The subaqueous soils that they found to be associated with these landforms were classified into six different subgroups according to Soil Taxonomy (1999). The major soils associated with the landforms identified in Ninigret Pond are shown in Table 2-4. The distribution of the subaqueous soils across the landforms supported the use of soil- landscape paradigm and the models created for Sinepuxent Bay, MD were enhanced to accommodate the soils described in Rhode Island. Osher and Flannagan (2007) studied the subaqueous soils in Taunton Bay, Maine a 1,300 ha shallow, mesotidal (mean tidal range is 2.7 m) estuary open to the Atlantic Ocean through Frenchman?s Bay. Osher and Flannagan (2007) delineated seven landforms based on photo tone, water depth, slope, and position on landscape. Landforms identified in Taunton Bay are different from those described in Rhode Island and Maryland due to the different processes that shaped the landforms and soils. Taunton Bay differed from these other coastal lagoons by the absence of a barrier island system and a much greater tidal range. The seven new landforms identified in Taunton Bay were named terrestrial edge, coastal cove, submerged fluvial stream, mussel shoal, fluvial marine terrace, channel shoulder, and channel. Ten different soil map units were identified and delineated according to slope class, geomorphic position, depositional 46 Table 2-4. Landforms and the associated soils found in Ninigret Pond, Rhode Island (Modified from Bradley and Stolt, 2003). Landscape Unit Classification (Soil Taxonomy Lagoon Bottom Typic Hydraquent Storm-surge Washover Fan Flat Typic Sulfaquent Flood-tidal Delta Flat Typic Psammaquent Storm-surge Washover Fan Slope Typic Fluvaquent Flood-tidal Delta Slope Typic Fluvaquent Mainland Submerged Beach Typic Endoaquent Barrier Cove Typic Sulfaquent Mainland Shallow Cove Typic Endoaquent Mid-lagoon Channel Typic Endoaquent Barrier Submerged Beach Typic Endoaquent Shoal Typic Endoaquent Mainland Cove Thapto-Histic Hydraquent 47 environment, and soil characteristics. The major soil map units and the soils associated with the landforms identified in Taunton Bay are presented in Table 2-5. In conjunction with this study, Jespersen and Osher (2006) estimated the carbon stored in subaqueous soils of Taunton Bay, Maine. The average organic carbon content in the upper 100 cm of the estuarine soils was 2.4% with an average bulk density of 0.67 g cm -3 . The organic C content within soils of the estuary was 136 Mg C ha -1 , which was greater than the C content in Maine?s subaerial soils. The soil map units identified by Osher and Flannagan (2007) were regrouped based on the depth of the fine estuarine parent material and landscape position. The submerged fluvial stream and marshes had the highest organic C content with 177 Mg C ha -1 and the recently submerged edges and coves had the lowest organic C content with 67 Mg C ha -1 . The data collected in this study provided valuable data for regional and global C budgets. There are several other subaqueous soil investigations currently underway. Coppock et al. (2003) is working on the subaqueous soil inventory of a 5,000 ha coastal lagoon in Rehoboth Bay, Delaware. Coppock et al. delineated 22 landform units throughout Rehoboth Bay. Eleven subaqueous soil map units were delineated and were differentiated based on texture, the presence or absence of sulfidic materials, and occurrence of buried organic horizons (Coppock, 2003). Payne and Stolt (2006) are investigating subaqueous soils in Little Narragansett Bay, Greenwich Bay, and Wickford Harbor, RI. Between 40 and 45 individual soil-landscape units have been identified and delineated based on slope, water depth, surficial geology, and geographical location. The dominant landforms identified include: bay bottom, depositional shoreline platform, mainland cove, fluviomarine bottom, and submerged beach. Several anthropogenic 48 Table 2-5. Landforms and the associated soils found in Taunton Bay, Maine (Modified from Osher and Flannagan, 2007). Landscape Unit Soil Map Unit Classification (Soil Taxonomy) Terrestrial Edge Submerged Marsh Submerged Beach Submerged Fluvial Delta Terrestrial Edge Fine-silty, Typic Sulfaquents Coarse-loamy, Haplic Sulfaquents Sandy, Haplic Sulfaquents Coarse-loamy, Sulfic Endoaquents Coastal Cove Shallow Coastal Cove Deep Coastal Cove Coarse-loamy, Haplic Sulfaquents Coarse-silty, Typic Sulfaquents Submerged Fluvial Stream Submerged Fluvial Stream Fine-silty, Typic Sulfaquents Mussel Shoal Mussel Shoal Fine-silty, Typic Sulfaquents Fluvial Marine Terrace Fluvial Marine Terrace Fine-silty, Typic Sulfaquents Channel Shoulder Channel Shoulder Fine-silty, Typic Sulfaquents Fine-silty, Typic Endoaquents Channel 49 landform units were identified; these include marina units, dredged channels, and dredge deposit shoals. Submerged Aquatic Vegetation Habitat Requirements Subaqueous soil information collected in coastal estuaries and lagoons could make considerable contributions to estuarine research and restoration efforts. Due to increased eutrophication of many estuaries, submerged aquatic vegetation (SAV) restoration studies have been focused on water quality parameters affecting the availability of light for photosynthesis. However, in areas where the water quality is not limiting other parameters have the potential to control the suitability of the site for SAV growth (Batiuk et al., 2000). Several studies have begun to recognize sediment characteristics as another important factor affecting the seagrass distribution. Sediments can impact the growth, morphology, and distribution of seagrasses due to erosional/depositional processes, availability of nutrients, and presence or absence of phytotoxins. Several sediment characteristics have been documented to impact the growth and success of SAV including porewater sulfide concentration, organic matter content, and grain size distribution. An overview of these studies is presented in Table 2- 6. Hydrogen sulfide is a known phytotoxin to wetland macrophytes including Spartina alterniflora, Spartina townsendii, Panicum hemitomon, and rice plants (Koch and Mendelssohn, 1989; Goodman and Williams, 1961; Okajima and Takagi, 1953). In hydroponic experiments, Goodman and Williams (1961) demonstrated that the addition of 0.94 mM H 2 S caused Spartina townsendii rhizomes to become ?soft rotted? and in similar studies, Koch and Mendelssohn (1989) demonstrated that the addition of 1.0 mM 50 Table 2-6. Summary of sediment characteristics defining habitat constraints for submerged aquatic vegetation in fresh water and marine environments. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Sulfide concentrations Zostera marina Polyhaline 200 to >800 ?M <200 ?M >400 ?M Laboratory experiment in Chincoteague Bay, MD using mesocosms collected from Chincoteague Bay sediments and to treated to reduce or increase ambient sulfide levels to study the impact on photosynthesis Goodman et al 1995 <6.5 ?M in porewater unvegetated sites 1.1 to 43 ?M in porewater vegetated sites AVS and CRS 0.6 to 3.2?M cm -3 (0.02 to 0.5 g kg -1 ) Field study in Roskilde Fjord, Denmark measuring biomass and sediment sampling. Holmer and Nielsen 1997 72.7 ?M Field study Roskilde Fjord, Denmark examining the effect of the addition of sucrose on sediment conditions. Terrados et al. 1999 < 5 g kg -1 Chromium reducible sulfides Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 51 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Sulfide Concentrations Zostera marina Polyhaline 0.3 to 1.5 g kg -1 Acid volatile sulfides Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 Ruppia maritima < 5 g kg -1 Chromium reducible sulfides Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Seagrasses >200 ?M Review of literature. Kemp et al. 2004 <100 ?M >400 ?M Compilation of data from literature, suggested values only. Koch 2001 Thalassia testudinum 350 to 1000 ?M <100 ?M >200 ?M Field study in Florida Bay. Carlson et al. 1998 < 2000 ?M Compilation of data from literature, suggested values only. Koch 2001 Thalassia hemprichii 2.3 ?M Field study examining the effect of the addition of sucrose on sediment conditions. Terrados et al. 1999 Cymodocea nodosa 50.2 ?M Field study examining the effect of the addition of sucrose on sediment conditions. Terrados et al. 1999 Organic Matter Zostera marina 0.4 to 0.5 % organic matter Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 52 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Organic Matter Zostera marina Polyhaline 0.8 to 1.4 % organic matter Field study in Chesapeake Bay measuring biomass and sediment sampling. Orth 1977 0.9 to 3.4 % organic carbon <2 % organic carbon >3 % organic carbon Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 0.2 to 7 % organic carbon Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 <4 % organic carbon Observations made in Taunton Bay, ME during soil sampling. Osher and Flannagan 2007 Ruppia maritima 0.9 to 3.4 % organic carbon <2 % organic carbon >3 % organic carbon Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Mesohaline <2 % organic matter Field study in Chesapeake Bay examining suspended particulate material in vegetated areas. Ward et al. 1984 Halodule wrightii Polyhaline 0.4 to 0.5 % organic matter Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 Thalassia testudinum Avg. 0.78% organic carbon Field study in Laguna Madre, TX. Lee and Dunton, 2000 1.5 to 4.6% organic carbon Field observations in reef lagoon of Puerto Morelos in Mexico. Enriquez et al. 2001 Syringodium filforme 1.5 to 4.6% organic carbon Field observations in reef lagoon of Puerto Morelos in Mexico. Enriquez et al. 2001 53 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Organic Matter Seagrasses Fresh water to polyhaline 0.8 to 16.4 % organic matter <5 % organic matter 6.5 to 16.4 % organic matter Compilation of data from literature, suggested values only. Koch 2001 <5 % organic matter >5 % Review of literature. Kemp et al. 2004 Hydrilla verticillata Fresh water 1 to 65 % organic matter <5 % organic matter > 20% organic matter Laboratory growth experiments on sediments collected from 17 North American lakes. Barko and Smart 1986 5 to 20% organic matter <5 % organic matter > 10% organic matter Greenhouse experiments using sediments from Lake Washington, WA with five organic matter additions Barko and Smart 1983 Elodea Canadensis 5 to 20% organic matter <5 % organic matter > 10% organic matter Greenhouse experiments using sediments from Lake Washington, WA with five organic matter additions Barko and Smart 1983 Myriophyllum spicatum 5 to 20% organic matter <5 % organic matter > 10% organic matter Greenhouse experiments using sediments from Lake Washington, WA with five organic matter additions Barko and Smart 1983 1 to 65 % organic matter <5 % organic matter > 20% organic matter Laboratory growth experiments on sediments collected from 17 North American lakes. Barko and Smart 1986 Grain Size Zostera marina Polyhaline Sandy substrates Observational study in Chesapeake Bay, MD. Hurley 1990 Sand to sandy loam Loamy sand Silt loam Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 54 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Grain Size Zostera marina Polyhaline Coarse sand to silt loam Very fine sandy loam to silt loam Coarse sand to very fine sand Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 5 to 11 % silt and clay Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 85 to 92% sand Field study in Chesapeake Bay measuring biomass and sediment sampling. Orth 1977 Silt Loam Field observations in Taunton Bay, ME Osher and Flannagan 2007 Cobble free and < 70% silt/clay Site selection model, Preliminary Transplant Suitability Index (PTSI) for identification of potential Zostera marina habitat in New Hampshire. Short et al 2002 Ruppia maritima Silt/clay mixture to coarse sand Fine to medium sand Experimental using grain sizes of ground glass. Seeliger and Koch (unpublished) Sand to sandy loam Loamy sand Silt loam Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Soft muddy sediments to sandy substrates Sandy substrates Observational study in Chesapeake Bay, MD. Hurley 1990 Halodule wrightii 5 to 11 % silt and clay Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 55 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Grain Size Halodule wrightii Polyhaline High quantities of sand, low quantities of silt and clay Field descriptive study in Apalachee Bay, northeast Gulf Coast of Florida. Livingston et al. 1998 Thalassia testudinum High quantities of sand, low quantities of silt and clay Field descriptive study in Apalachee Bay, northeast Gulf Coast of Florida. Livingston et al. 1998 Syringodium filforme High quantities of sand, low quantities of silt and clay Field descriptive study in Apalachee Bay, northeast Gulf Coast of Florida. Livingston et al. 1998 Seagrasses Marine/ estuarine 0.4 to 72% silt and clay (<63 ?m) <20% silt and clay Compilation of data from literature, suggested values only. Koch 2001 0.4 to 72% silt and clay (<63 ?m) <20 to 30% silt and clay (by weight) Review of literature. Kemp et al. 2004 Seagrass meadows Polyhaline 1 to 50% silt and clay <10% silt and clay >20% silt and clay Field study in Andaman coast of Southern Thailand and Western Philippines coast. Terrados et al. 1999 Potomogeton perfoliatus Fresh water to mesohaline Firm muddy sediments Observational study in Chesapeake Bay, MD. Hurley 1990 Hydrillia verticillata Fresh water Silt to muddy substrates Observational study in Chesapeake Bay, MD. Hurley 1990 56 Table 2-6. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Sediment Density Zostera marina Polyhaline Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Dense sands Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 Ruppia maritima Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Myriophyllum spicatum Fresh water to mesohaline 0.1 to 1.3 g ml -1 0.2 to 0.9 g ml -1 <0.2 or >0.9 g ml -1 Laboratory growth experiments on sediments collected from 17 North American lakes. Barko and Smart 1986 Hydrillia verticillata Fresh water 0.1 to 1.3 g ml -1 0.2 to 0.9 g ml -1 <0.2 or >0.9 g ml -1 Laboratory growth experiments on sediments collected from 17 North American lakes. Barko and Smart 1986 57 H 2 S resulted in lower biomass of marsh grass species Spartina alterniflora and Panicum hemitomon. Okajima and Takagi (1953) showed limited rice above ground growth and root hair development in the presence of 1.0 mM H 2 S. It has also been demonstrated that porewater sulfide is toxic to estuarine and marine SAV species. Seagrasses inhabit sediments that are often anoxic below the upper 2 to 3 cm and may be highly reduced due to the presence of sulfides in the porewater (Terrados et al., 1999). In organic-rich sediments the sulfide concentrations are often elevated and extended periods of sediment hypoxia have been associated with the decline of Thalassia testudinum (Carlson et al., 1994; Koch, 1999). However, oxygen produced during photosynthesis by seagrasses may be transported through the roots into the rhizosphere. Thus, reduced compounds in the sediments, such as iron and sulfides, become oxidized by the released oxygen creating a less toxic environment for the seagrasses. Elevated porewater sulfide levels may contribute to seagrass die-off in areas with extra stresses such as decreased light availability due to water column turbidity or shading by macroalgae or epiphytes (Lee and Dunton, 2000). In Florida Bay, porewater sulfide concentrations were higher in die-off areas than healthy seagrass beds (Thalassia testudinum), suggesting that the sulfide toxicity may be a factor in seagrass loss (Carlson et al., 1994). Correlations between porewater sulfide concentrations and growth of Thalassia testudinum have indicated that concentrations above 100 ?M may be toxic (Carlson et al., 1994), which was similar to observations by Goodman et al. (1985). They demonstrated that mesocosm sediments with sulfide concentrations between 100 and 200 ?M had a negative impact on photosynthesis in Zostera marina. Due to the ephemeral and 58 transitory nature of porewater sulfide in these environments it is often difficult to quantify (Carlson et al., 1994). Sediment sulfide concentrations, as sulfide bearing minerals, could be used as a surrogate in estimating the concentration of soluble sulfide in estuarine/marine environments. It can be reasoned that sediments with higher soluble sulfide generation have an increased likelihood for sediment sulfide accumulation as monosulfides and disulfides. The concentration of solid phase sulfides in these sediments is less ephemeral and more easily obtainable in these environments. Thus these data could be used to indicate the potential for sulfide toxicity. In Sinepuxent Bay, MD, where sediment sulfide concentrations were measured in areas with healthy Zostera marina and Ruppia martima beds the levels were less than 5 g kg -1 (Demas and Rabenhorst, 1999). These values were greater than concentrations measured by Bradley and Stolt (2006) in sediments supporting healthy Zostera marina where concentrations were less than 1.5 g kg -1 and in Demark sediments supporting Zostera marina had values less than 0.5 g kg -1 (Holmer and Nielsen, 1997). Although the studies examining the relationship between sediment sulfide concentrations and SAV growth are limited, we can reasonably surmise that low sediment sulfide concentrations are favorable for healthy SAV habitats. Organic matter in submerged sediments has been shown to have a positive effect on plant growth, due to the release of nitrogen and phosphorus during the mineralization of the organic matter (Sand-Jensen and Sondergaard, 1979). However, at high quantities organic matter have a negative effect on the growth of submerged macrophytes probably due to their contribution to the formation of phytotoxins, such as S 2- in brackish sediments (Barko and Smart, 1983). Barko and Smart (1983) 59 demonstrated using laboratory experiments that the growth of fresh water SAV was limited to sediments containing less than 5% organic matter and SAV growth diminished at levels greater than 5% organic matter. In the Mid-Atlantic region healthy Zostera marina has been observed growing on sediments with organic matter contents less than 2% (Orth, 1977; Ward et al., 1984; Demas, 1998). However in Rhode Island, Bradley and Stolt (2006) found Zostera marina growing on soils with higher organic matter contents (up to 4%) than in the Mid-Atlantic region. In warmer climates, Thalassia testudinum was observed on sediments with organic carbon levels of 0.8 to 4.6%, which is similar to the Mid-Atlantic region (Lee and Dunton, 2000; Enriquez et al., 2001). The limitation of higher organic matter content on SAV growth is not well understood (Koch, 2001) although it may be related to nutrient limitation in very fine sediments associated with high organic deposits (Barko and Smart, 1986) or to high sulfide concentrations associated with increased reduction of sulfate and organic matter oxidation (Nienhus, 1983; Goodman et al., 2005). Overall the organic matter content of sediments supporting healthy Zostera marina and Ruppia martima was generally less than 5% (3% organic carbon) (Table 2-6). Submerged aquatic vegetation growth is also impacted by physical and geochemical processes that are associated with grain size distribution (Barko and Smart, 1986). In experiments using glass beads, Seeliger and Koch (unpublished) found that Ruppia maritima had maximum growth in fine to medium sand-sized particles. Demas (1998) observed Zostera marina and Ruppia martima growing on loamy sand (<15 % silt and clay) soils in Sinepuxent Bay, MD, which was similar to observations made by Orth (1977) in the Chesapeake Bay where Zostera marina was 60 growing on sediments with 85 to 92% sand. Hurley (1990) also made observations in regard to the type of sediments inhabited by several SAV species in Chesapeake Bay, including Zostera marina which grew primarily on sandy substrates and Ruppia maritima that was occasionally found on soft muddy sediments but was more commonly on sandy substrates. In contrast to these Mid-Atlantic based studies, Bradley and Stolt (2006) observed Zostera marina growing on soils in Ninigret Pond, RI, with greater quantities of silt (>21%) and clay (>8). Observations collected by Osher and Flannagan (2007) in Taunton Bay, ME, also described Zostera marina growing on finer textured (silt loam) soils. According to a review of Kemp et al. (2004), Zostera marina and Ruppia maritima are generally more abundant in sediments in which silts and clays constitute less than 20 to 30% (by weight). However, several studies (Bradley and Stolt, 2006; Osher and Flannagan, 2007) indicated that healthy Zostera marina beds were located on sediments with higher amounts of silt and clay. Short et al. (2002) developed a three phase site selection model for Zostera marina transplant projects. In this model a general rule was derived from the literature indicating that the preferred sites have sediment conditions that were cobble free and contained less than 70% silt and clay. Grain size distribution impacts the rate of porewater exchange in the sediments and the amount of nutrients in the sediments. Grain size distributions that are skewed towards silt/clay have lower porewater exchange rates with the overlying water column than sandier sediments (Huettel and Gust, 1992), which can lead to increased nutrient levels but also higher sulfide concentrations in the sediments and porewater (Kenworthy et al., 1982; Holmer and Nielsen, 1997). In higher salinity (18 61 to 30 ppt) environments it seems as though SAV prefer to inhabit more oxygenated coarser textured sediments (Koch, 2001) that permit higher porewater exchange with the overlying water, which helps maintain tolerable sulfide concentrations in these soils. Sediment density was another factor that has been shown to influence the growth of submersed fresh water macrophytes, Myriophyllum spicatum and Hydrilla verticillata (Barko and Smart, 1986). Densities of 0.9 to 1.3 g ml -1 occurred in sediments with sand contents >75% and these sediments resulted in reduced growth. Barko and Smart (1986) attributed the reduced growth in these high density sediments to low natural fertility levels associated with these extremely sandy sediments rather than the density itself. Densities of 0.2 g ml -1 or less and high organic matter contents also resulted in diminished growth, which the authors attributed to longer diffusion distances (greater tortuosity) that resulted in lower nutrient uptake. In Sinepuxent Bay, MD, Demas (1998) noted the absence of SAV on extremely sandy soils with higher densities. He also attributed the lack of SAV growth on these soils to low fertility levels and difficulty in roots penetrating the dense sands. In a similar field study, Bradley and Stolt (2006) also suggested that Zostera marina colonization may be hindered on dense sandy or gravelly soils which have physical characteristics which impede rhizome elongation and nutrient levels. However, Demas (1998) and Bradley and Stolt (2006) did not conclusively determine a density that negatively impacts the health of SAV in these environments and the lower inherit fertility of these materials also complicates the interpretation. 62 The sediment factors impacting SAV growth and distribution in estuarine and marine environments are not completely independent factors as presented. As wave and current energies decrease, finer sediments and organic matter collect in these low energy environments. These low-energy environments are also conducive for sediment sulfide generation. Thus, the areas with finer textured sediments tend to have higher organic matter and sediment sulfide contents compared to the high- energy environments. The seagrasses reproduction and recruitment also plays a role in the location and distribution in estuarine environments. Orth et al. (1994) broadcast Zostera marina seeds into three unvegetated plots in the Chesapeake Bay (York River, VA) which historically supported vegetation. The seedlings were distributed within 5 m plots, but not beyond these areas. They suggested that the seeds were protected from current flows by microtopographic features (burrows, pits, mounds, and ripples) and demonstrated that seeds settled rapidly and became incorporated into the sediments. These results suggest that seeds stay locally where they were distributed and do not tend to have large scale distribution patterns. Thus, the seed distribution should be taken into consideration in restoration of large landscapes. 63 Chapter 3: Topographic Analysis and Subaqueous Landforms Introduction Traditionally, shallow-water mineral substrates have been studied only by geologists. These sediments were generally sampled using regularly spaced grid patterns (Wells et al., 1994), which were utilized because the spatial relationships among the sediments were not established and there was an underlying assumption that sediment variability was more random than systematic (Wilding and Drees, 1983). Sediments were typically sampled to some fixed depth (< 30 cm) rather than by layer or horizon. As a result of this sampling method, often samples would be composed of a combination of the surface and subsurface materials (horizons). The grid pattern sampling has limited the development and understanding of sediment spatial relationships as it relates to landforms (Demas and Rabenhorst, 2001). Demas et al. (1996) proposed the application of a pedologic paradigm for the mapping of subaqueous soils found in subtidal habitats. They subsequently demonstrated that soil horizons formed in shallow water substrates due to pedologic processes, and that shallow water substrates should be considered subaqueous soils that can be accommodated under a pedologic paradigm (Demas and Rabenhorst, 2001). Topographic maps are often used as base maps during landscape analysis because landscape units can be delineated based on slope and land-surface shape. As is true with subaerial landscapes, subaqueous landscapes possess discernable 64 topography from which specific landforms can be identified (Demas, 1998; Bradley and Stolt, 2003). Traditional methods used in landscape analysis, such as stereo-photo interpretation and visual assessment of the landscape, have only limited application in submerged environments because the subaqueous landscape units cannot be easily observed in water deeper than 1 m or so. However, in very shallow water these photographs are helpful in identifying specific landforms, such as storm-surge washover features behind barrier islands. Overall, one of the most useful tools in assessing the types of underwater landforms is the development or acquisition of subaqueous topography or bathymetry (Demas, 1998; Bradley and Stolt, 2002). Topographic information on the subaqueous landscape can be acquired by using bathymetric methods (Demas and Rabenhorst, 1998). Traditionally, bathymetric data are collected by using acoustic soundings, which utilize radio waves transmitted from a transducer head. Water depth is calculated from the time between the transmission and the reception of the reflected signal. In tidal settings, the data set must also be corrected for tidal fluctuations, because the water depths change due to tides. One limitation to using acoustic soundings is that data cannot be collected in very shallow areas, because the water is not deep enough to accommodate the boat draught and transducer head. This limitation can be overcome if the data in shallow areas are collected during exceptionally high tides. Development of a subaqueous topographic map of detail sufficient to perform terrain analysis for the identification and delineation of subaqueous landforms requires a high density and accurate data set. Demas (1998) collected bathymetric data for Sinepuxent Bay, MD at an average density of 0.06 ha per sounding in order to create an accurate bathymetric map. Using 65 this detailed map, he was able to identify subaqueous landforms in Sinepuxent Bay, MD. Subaqueous landforms and soils have been identified and described in several Atlantic coastal lagoons including Sinepuxent Bay, MD (Demas, 1998), Ninigret Pond, RI (Bradley and Stolt, 2003), Rehoboth Bay, DE (Coppock et al., 2003), and Taunton Bay, ME (Flannagan, 2005). The subaqueous landscapes have been delineated based on submerged topography, land-surface shape, geographic location, water depths, and depositional environments. The types of subaqueous landforms that have been identified in previous studies include barrier coves, dredge channels, flood- tidal delta flats, flood-tidal delta slopes, lagoon bottoms, mainland coves, shoals, storm-surge washover fan flats, and storm-surge washover fan slopes (Table 3-1). The objectives of this study were to 1) to acquire or develop a subaqueous topographic dataset for Chincoteague Bay; and 2) to identify and describe the subaqueous landforms of Chincoteague Bay. Materials and Methods Study Area Chincoteague Bay is the largest of Maryland?s inland coastal bays with an area of 19,000 ha (in the Maryland portion). It is bounded by Assateague Island to the east and the Maryland mainland to the west and is connected to the Atlantic Ocean by the Ocean City inlet to the north and the Chincoteague inlet to the south (Figure 3-1). Chincoteague Bay?s water depths range mostly from 1.0 to 2.2 m; with an approximate daily tidal range of 10 to 20 cm (Wells et al., 2004). 66 Table 3-1. Subaqueous landforms commonly found in Atlantic coastal lagoons. Definitions adapted from Subaqueous Soils Subcommittee, 2005. SUBAQUEOUS LANDFORMS DEFINITION Barrier Cove Area adjacent to barrier island that forms an embayment or cove. Dredge Channel A linear, deep channel created by dredging for navigational purposes. Flood-tidal Delta A landform created as sand-sized particles accumulate from the flood tide entering the tidal inlet; are usually multi-lobed and are unaffected by ebb tides. Flood-tidal Delta Slope Extension of the flood-tidal delta that slopes towards the lagoon bottom. Fluviomarine Bottom A nearly level or slightly undulating, relatively low- energy, depositional environment with relatively deep water (1.0 to >2.5 m) directly adjacent to an incoming stream and composed of interfingered and mixed fluvial and marine sediments (fluviomarine deposits). Lagoon Bottom Central portion of low-energy, depositional basin. Mainland Cove Area adjacent to mainland coast that forms an embayment or cove, usually below the wave base. Shoal An area that is substantially shallower than the surrounding area. Storm-surge Washover Fan Flat An area created by the overwash from storm-surges that carry sandy sediments from the barrier dunes into the adjacent lagoon. Storm-surge Washover Fan Slope Extension of the storm-surge washover fan flat that slopes towards the lagoon bottom. 67 Figure 3-1. The Delmarva Peninsula and the inland coastal bays of Delaware, Maryland, and Virginia (Biggs, 1970). 68 Bathymetric Data Collection During the summer of 2003 the Maryland Geological Survey (MGS) collected over 600,000 geo-referenced fathometer soundings at a density of 0.032 ha per sounding (Figure 3-2) in the Maryland portion of Chincoteague Bay (Wells et al., 2004). As part of this study, a second bathymetric data set was collected to spot check the MGS fathometer soundings using a Raytheon DE-719C marine research fathometer (Raytheon Company, MA). These bathymetric surveys were made in August and November 2003. The survey consisted primarily of cross sections and edge surveys. The fathometer was calibrated prior to data collection and checked periodically. The fathometer has accuracy to within 1 cm once calibrated. The fathometer is limited to water deeper than 60 cm, due to boat draft and the minimum depth requirements of the transducer. Over 7400 geo-referenced fathometer soundings (Figure 3-3) were collected in the 4600 ha study area (approximately 0.62 ha per sounding). The high resolution orthomosaic photograph used in Figures 3-2, 3- 3, 3-5, 3-6, 3-7, 3-8, 3-9, and 3-10 was provided by USDA-NRCS Geospatial Data Branch in Fort Worth, TX (USDA-NRCS, 2001). Location data was collected utilizing a Rockwell PLGR+ PPS Global Positioning System (GPS) unit (Rockwell International, WI). The operation of the GPS unit required downloading of the almanac for the day prior to data collection, to obtain maximum accuracy. A Figure of Merit (FOM) value of 1 ensured an accuracy level of 1 m in unobstructed areas, such as Chincoteague Bay (Rockwell Corp. Staff, 1994). The location data collected was monitored to maintain FOM 1 levels. 69 Figure 3-2. Point data collected for the Maryland portion of Chincoteague Bay by the Maryland Geological Survey, from May through September 2003 using differential global positioning system techniques and digital dual frequency echo sounding equipment. Water level data was also collected at four locations within the study area and were used to correct the echo soundings for tide and wind offsets (Wells et al., 2004). 70 Figure 3-3. Location of bathymetric data collected in August and November, 2003 in a 4600 ha study area of Chincoteague Bay, MD using a fathometer that utilizes acoustic soundings. The average density of measurements was approximately 0.62 ha per sounding. 71 The GPS unit and fathometer were connected to a laptop computer equipped with GeoLink 6.1 XDS software (Michael Baker Corporation, 2004). The software provided the capability to simultaneously record the time of day, ?real time? GPS data locations, and fathometer soundings. Data were collected at a boat speed of approximately nine kilometers per hour with soundings and locations collected every five seconds. This resulted in soundings spaced approximately 12 to 15 m apart. A Remote Data Systems WL40 Tide Gauge was installed on a piling at the entrance of the inlet to the Public Landing boat ramp to record tide data during the same days that bathymetric data were collected (Figure 3-4). Tide heights were recorded every five minutes. The tide gauge calibration point was set at 0 mean sea level (MSL) through an elevation survey linked to National Ocean Service tidal station disk 3034, located on the bottom concrete step on the south side of the Driscoll residence, located on the corner of Public Landing Road and Public Landing Wharf Road (38? 8? 57.7? N, 75? 17? 13.9? W). These data were later used to normalize all of the fathometer soundings to depth below MSL. The mainland and barrier island shorelines were hand-digitized using ArcMap 9.0 (ESRI Inc., 2006) and assigned 0 MSL prior to creating bathymetric maps. A bathymetric map was created using ordinary kriging with a spherical model and nearest neighbor of 12 in ArcMap 9.0 geostatistical analyst. 72 Figure 3-4. Tide data collected in Chincoteague Bay during August, 2003 (A) and November, 2003 (B) near Public Landing, Maryland. 73 Evaluation of Maryland Geologic Survey Data In order to evaluate the quality of the bathymetric data collected by MGS, the data set was compared with the smaller data set generated independently as part of this study. The bathymetric data sets were assessed by using a spatial join in which all of the data points from the two data sets that were within a 20 m distance of each other were compared. Due to the high point density of the MGS data set along transects (4.5 m between points) relative to the distance between transects (approximately 400 m), we decided to remove four-fifths of the data points from the MGS data set (saving every fifth point) to create a bathymetric map with an average point density of 0.45 ha per sounding. The bathymetric map (using one-fifth of the MGS data points) was created by using ordinary kriging with a spherical model and nearest neighbor of 9 in ArcMap 9.0 geostatistical analyst (ESRI Inc., 2006). A slope map was created using ArcMap 9.0 spatial analyst with a 30 m cell size. Landform Delineation Landforms in the study area were identified by using water depth, slope, landscape shape, depositional environment, and geographical setting based on the DEM and high resolution photography. The high resolution orthomosaic photographs for Worcester County, Maryland, were provided by USDA-NRCS Geospatial Data Branch in Fort Worth, TX (USDA-NRCS, 2001). The defining criteria for the landforms are presented in Table 3-1. Landforms were delineated by hand digitizing the outline in ArcMap 9.0 (ESRI Inc., 2006). 74 Results and Discussion Subaqueous Topographic Maps Navigation charts typically display bathymetric data as Mean Lower Low Water, but the MGS data set was collected as Mean Sea Level (MSL) data, which was reported relative to the North American Vertical Datum of 1988 (NAVD88). The data collected using NAVD 88 provides a more accurate depiction of the bay topography compared to data adjusted to Mean Lower Low Water (Wells et al., 2004). The bathymetric data set we collected for the central portion of Chincoteague Bay was used to create the bathymetric map shown in Figure 3-5. The water depths range from 0 to 250 cm below MSL. An initial bathymetric map for the entire bay was created from the MGS data set and is shown in Figure 3-6. The water depths for the entire Maryland portion of Chincoteague Bay range from 0 to 250 cm below MSL. The comparison of the bathymetric data generated by the MGS and University of Maryland (UMD) is shown in Figure 3-7. There was a strong linear relationship between the datasets (r 2 =0.90) and the regression line was very similar to the 1:1 line. There was more scatter at shallower depths and vegetation in these areas could have contributed to these differences. The mean difference between the two data sets was 2.7 cm and given the variability, was deemed to be a non-significant, and thus acceptable, error. A graph showing the frequency distribution of error between the two data sets is presented in Figure 3-8. Most of the pairs of points (80%) fall within ?15 cm of the mean of 2.7 cm. Since the observed error between the data sets was minor, we were satisfied that the MGS data set was generally accurate. 75 Figure 3-5. Subaqueous topographic map of Chincoteague Bay created by kriging the data we collected in ArcMap using geostatistical analyst. Contour intervals are 100 cm and were generated using spatial analyst surface analyst in ArcMap. 76 Figure 3-6. Subaqueous topographic map of Chincoteague Bay created by kriging the Maryland Geologic Survey data set in ArcMap using geostatistical analyst. Contour intervals are 100 cm and were generated using spatial analyst surface analyst in ArcMap. 77 Figure 3-7. Comparison of the water depths measured by the Maryland Geological Survey (MGS) and our study. The points compared were positioned less than 20 m apart. The 1:1 line is shown as a solid black line. 78 Figure 3-8. Frequency distribution of the depth differences observed between the Maryland Geological Survey bathymetric data sets and the data set we collected. The pairs of points compared were positioned within 20 m from each other. The data are normally distributed with a mean of 0.027 m, which given the variability, was deemed to be a non-significant, and thus acceptable, error. 79 Subaqueous Landforms Landscape units were delineated in Chincoteague Bay based on water depth, slope gradients, landscape shape, depositional environment, and geographical relationships. The slopes of the subaqueous soil surface in Chincoteague Bay ranged from 0 to >0.35 %, and are shown in Figure 3-10. Most of the slopes in Chincoteague Bay are very subtle with less than 0.1% slope. Several landforms have a distinctive shape. For example, washover fans have a lobate shape, which can easily be identified and delineated using bathymetry and aerial photography. Geographical relationships within the bay, such as the proximity to the barrier island, mainland, or mouth of a tidal creek or river, were used to help identify several landforms. For example, washover fan landforms occur in shallow water adjacent to the barrier island. The depositional environments within the bay (low-energy versus high-energy regions) were also used to identify several landforms. In shallow water areas within the bay, false color infrared photographs could be utilized to identify landforms and define their extent. Using the subaqueous topographic map of Chincoteague Bay, we delineated 30 distinct subaqueous landscape units, which belonged to 10 specific landform types. The names of these 10 landforms and their aerial extent are given in Table 3- 2. The location of these landforms in Chincoteague Bay is shown in Figure 3-10. The landforms identified in Chincoteague Bay were similar to landforms found in previously studied Atlantic coastal lagoons (Demas, 1998; Bradley and Stolt, 2003; and Coppock et al., 2004) even though Chincoteague Bay is much larger than the lagoons previously studied (for example Chincoteague Bay is 14 times larger than the 80 Figure 3-9. The subaqueous slope map of Chincoteague Bay was created using the Maryland Geological Survey data set with spatial analyst surface analyst in ArcMap. 81 Table 3-2. Subaqueous landscape units and cumulative extent in Chincoteague Bay, MD. Subaqueous Landform Number of landscape units Area ha (% of study area) Barrier Coves 2 1357 (6.4%) Dredged Channel 1 123 (0.6%) Fluviomarine Bottom 1 1148 (5.4%) Lagoon Bottom 1 10501 (49.5%) Mainland Coves 10 1544 (7.3%) Paleo-flood Tidal Delta 1 971 (4.6%) Shoals 4 1018 (4.8%) Storm-surge Washover Fan Flat 3 1926 (9.1%) Storm-surge Washover Fan Slope 1 1849 (8.7%) Submerged Wave-cut Headland 8 1556 (7.3%) 82 Figure 3-10. Subaqueous landforms delineated in Chincoteague Bay were hand- digitized using ArcMap. The subaqueous landforms were delineated based on slope, water depth, geographic location, and depositional environment. 83 adjacent Sinepuxent Bay). The landforms in Chincoteague Bay are larger and there are more landscape units than in lagoons previously studied. The number of landscape units and cumulative extent of each subaqueous landform is shown in Table 3-2. The paleo-flood tidal delta and the submerged wave-cut headland are newly described features that have not been identified in previously studied Atlantic coastal lagoons. A brief description of each of the 10 landforms follows below. Adjacent to the barrier islands are storm-surge washover fan flats that are broad, flat, fan-shaped or lobate features. These features tend to be sandy, gently sloping (less than 0.15%), and shallow with water depths ranging from 0.0-1.00 m. These areas are created as overwash from high-energy storm surge transport of sediments from the seaside of the barrier island and are deposited in the adjacent coastal lagoon. The storm-surge washover fan flat is the second most extensive unit in Chincoteague Bay. The storm-surge washover fan slope is a landform that slopes away from the storm-surge washover fan flats towards the lagoon bottom. These units are sandy, and are moderately to strongly sloping (0.06-0.45%). The water depth ranges from 1.00- 1.50 m. The steepest slopes in the bay are found on this landform. The paleo-flood tidal delta landform is a relict fan-shaped deposit of sand- sized sediments that were transported through an inlet (in this particular case, Green Run Inlet) (Figure 2-5). The paleo-flood tidal delta is found adjacent to the barrier island in the southern portion of the bay and is nearly level (slope less than 0.10%) with water depths ranging from 0.20 to 1.00 m. During its formation, the flood tidal delta was a high-energy depositional area impacted daily by tidal cycles. The 84 sediment was transported through the inlet and over a flood tidal ramp where the current slowed and dissipated and the coarser particles were deposited. In lagoons examined in previous studies (Demas, 1996; Bradley and Stolt, 2003; Coppock et al., 2004), active inlets were recognized and the associated landform was a flood-tidal delta. There are currently no active inlets in the Maryland portion of Chincoteague Bay, but there is evidence of past inlets and the relict flood-tidal deltas are still present. Barrier coves are semi-enclosed areas adjacent to the barrier island. These are gently sloping (less than 0.1%) areas with water depths ranging from 0.2-1.50 m. Thus, they are low-energy depositional areas, which allow finer-textured materials (silts, clays, and organic materials) to settle out of suspension. Due to their proximity to the barrier island these areas often have a sandy cap due to washover events. Shoals are areas that are shallower than the surrounding area. Generally the shoals are moderately sloping (0.60% or less) and are found in water depths ranging from 1.00-1.50 m. In Chincoteague Bay the shoals are either depositional areas created from dredging projects or they may represent the remnants of old marsh islands. Dredged channels are deeper water areas within a lagoon that is maintained by dredging activities as shipping channels. These areas are linear and deeper that the surrounding areas. The dredged channel is the smallest of the landforms. The lagoon bottom is the low-energy central portion of the study area. The lagoon bottom is nearly level (slope less than 0.10%) and has the greatest water depth of all landforms. This portion of the study area is dominated by very slow current 85 speeds, which allows the finer-textured sediments to settle out of suspension. The lagoon bottom unit is the largest and most extensive portion of the study area. The fluviomarine bottom is a nearly level or slightly undulating, relatively low-energy depositional environment with water depths ranging between 1.0 to 1.5 m that is directly adjacent to an incoming stream, (in this study area, Scarboro Creek). The fluviomarine bottom is composed of mixed fluvial and marine sediments. In this environment, colloidal-sized detrital sediments carried in fresh water enter the higher salinity lagoon and in the fresh-saline water boundary the sediments become flocculated due the higher ionic strength of the saline water (Duinker, 1980). This process creates deposits with higher proportions of silt and clay. These deposits also have a very high n value (very low bearing capacity) and lower bulk density. Mainland coves are areas adjacent to the mainland that form an embayment along the coast. The mainland coves are gently sloping (0.0-0.20%) towards the lagoon bottom with water depths shallower than 1.50 m. These landforms are dominated by low tidal currents; water depth of these coves is below the wave base, which allows finer-textured suspended particles to settle out. The submerged wave-cut headland landform is a subaqueous, relict erosional landform produced by coastal wave erosion of headlands which are subsequently submerged by rising sea level or subsiding land surface. These units are moderately sloping (0.01-0.25%) with water depths that range from 1.00-1.50 m. These areas may contain marsh islands that were once connected to the mainland that are subjected to continuous wave erosion. 86 Conclusions The extensive bathymetric dataset collected by the MGS was deemed suitable for use since the observed error between the data sets was minor. This data set was used to create a detailed and accurate subaqueous topographic map that was suitable for identifying and delineating subaqueous landscape units. Ten subaqueous landforms were identified and delineated in Chincoteague Bay (barrier coves, dredged channel, fluviomarine bottom, lagoon bottom, mainland coves, paleo-flood tidal delta, shoals, storm-surge washover fan flat, storm-surge washover fan slope, and submerged wave-cut headlands). The landforms identified in this study were similar to subaqueous landforms identified in other Atlantic coastal lagoons (Demas, 1998; Bradley and Stolt, 2003; Coppock et al., 2004). However, we also identified two landforms not previously identified, which were the paleo-flood tidal delta and the submerged wave-cut headland. The terrain analysis and delineation of the landscape units were obtained in order to be utilized during the investigation of subaqueous soils in Chincoteague Bay. 87 Chapter 4: Characterization and Classification of Subaqueous Soils in Chincoteague Bay, MD Introduction The purpose of classification systems is ?to arrange objects in such an order that ideas precede or accompany one another in a way that provides the command of knowledge and leads to the acquisition of more knowledge? (Soil Survey Staff, 1975). Soil Taxonomy provides the structure to understand the relationships between soils and the factors responsible for their genesis. Soil Taxonomy is based on soil characteristics that are definable, measurable, and sampleable. It is primarily a morphological taxonomic system with strong genetic undertones. The taxonomic system is a hierarchical system with six categories, from broadest to most detailed, being order, suborder, great group, subgroup, family, and series. Classification schemes have been in development since the beginning of pedological research. Some of these schemes have, since their conception, included subaqueous materials as soils, whereas others did not include these materials in the beginning, but have subsequently considered these materials as soils. According to Hansen (1959) in the 1860?s Post (1862) developed a nomenclature for subaqueous soils. The terms ?gyttja? and ?dy? were introduced and described by v. Post as follows for limnic sediments: 1) ?gyttja is a copogenic formation consisting of a mixture of fragments from plants, numerous frustules from diatoms, grains of quartz and mica, silicous spicules from Spongilla, and exoskeletons from insects and 88 crustaceans? and 2) ?dy consists of the same constituents as gyttja, but to these is added some brown humus particles? (Hansen, 1959). The gyttja and dy soils differed on the amount of organic materials in the soils, with gyttja being organic rich and dy being organic poor. Kubiena (1953) proposed a soil classification system for Europe that included subaqueous soils, and were described using the terms developed by v. Post (1862). Kubiena?s classification system was an attempt to be comprehensive and included all soil types ?even the usually neglected sub-aqueous soils, so very important for a complete understanding of soil formation?. He noted that the sub- aqueous soils could become cultivated by the natural or artificial drying of these areas. Kubiena (1953) separated the sub-aqueous soils into two main categories 1) young soils always covered with water that do not form peat (our subaqueous soils); and 2) young sub-aqueous soils with peat formation (what would mostly be Histosols in emergent wetlands, bogs, and forests) (Table 4-1). The terms Kubiena used to describe the subaqueous soil classes are quite similar and seem to be differentiated based on organic matter type and content. These terms are not currently used in Soil Taxonomy or the World Reference Base. Therefore it is a difficult system to use in describing subaqueous soils. Kubiena also introduced horizonation of the sub- aqueous soil profiles, for example (A)C, AC, and AG-Soils, describing soils that do not have a distinct humus layer, those that do have a distinct humus horizon, and those with a humus layer underlain by a gleyed horizon, respectively. Muckenhausen (1965) proposed a soil classification system for the Federal Republic of Germany that included subhydric soils, and which used Kubiena?s subaqueous soil terms. Ponnamperuma (1972) described soils formed from river, lake, and ocean sediments 89 Table 4-1. Classification of Sub-Aqueous soils in Kubiena?s Soils of Europe (Modified from Kubiena, 1953). Sub-Aqueous Soils not Forming Peat Interpretation of the Soil I Protopedon Sediments without organic material accumulation Chalk deficient Protopedon Dystrophic lake iron Protopedon Lake Marl Protopedon Sea Chalk Protopedon II Dy Muds low in organic matter and nutrients III Gyttja Organic rich muds, high in nutrients Limnic Gyttja 1. Eutrophic Gyttja 2. Chalk Gyttja 3. Oligotrophic Gyttja 4. Dygttja Lake (fresh water) sediments Marine Gyttja 1. Schlickwatt Gyttja 2. Sandwatt Gyttja 3. Cyanophyceae Gyttja Marine (saline water) sediments IV Sapropel Dark colored sediments rich in organic matter Limnic Sapropel Lake (fresh water) sediments Marine Sapropel 1. Mudwatt Sapropel 2. Diatomwatt Sapropel Marine (saline water) sediments Peat Forming Sub-Aqueous Soils V Fen Emergent wetlands, bogs, Turf-Fen (Turf Peat Moor) 1. Phragmites-Fen (Reed Peat Moor) 2. Carex-Fen (Sedge Peat Moor) 3. Hypnum-Fen (Hypnum Peat Moor) and forests Wood-Fen (Swamp Wood Peat Moor) 90 and justified their inclusion as soils because the physical, mineralogical, and chemical processes that occur in these sediments are analogous to the processes that occur in subaerial soils. In the first edition of Soil Taxonomy (Soil Survey Staff, 1975), these subaqueous sediments were excluded as soils, due to the requirement that soils must be capable of supporting the growth of rooted plants. But perhaps a more important issue was related to the boundaries of soil. The first edition of Soil Taxonomy (1975) stated that the upper limit of soils is ??air or shallow water. At its margins it grades into deep water or to barren areas of rock or ice.? Thus, due to the permanent saturation of these materials under ?deep? water they were excluded. The definition of soils was changed in the second edition of Soil Taxonomy (1999) to accommodate among others, the recent research examining subaqueous materials as soils by Demas (1998). Even though much of his work was published at or after 1999, the work was done prior to this, and in fact, was to a large degree what led to the change in the definition. The new definition included materials as soils that either demonstrated the formation of soil horizons OR those materials that were capable of supporting growth of higher rooted plants. In addition the boundaries of soil were expanded so that the upper limit of soils became ??soil and air, shallow water, live plants, or plant materials that have not begun to decompose. Areas are not considered to have soil if the surface is permanently covered by water too deep (typically greater than 2.5 m) for the growth of rooted plants. Soil?s horizontal boundaries are where it grades into deep water, barren areas, rock, or ice? (Soil Survey Staff, 2006). These changes 91 allowed for subaqueous environments to be studied as soils due to the formation of pedogenic horizons. Because subaqueous soils typically show weak development of horizons, they generally have been classified as Aquents. But this classification fails to recognize that they are permanently under water. Recently the Subaqueous Soils Committee of the Northeast Regional Cooperative Soil Survey conference (2007) proposed modifications to Soil Taxonomy to better accommodate these soils. In particular, they proposed the suborder of Wassents (Appendix A). The differentiating criterion to identify the Wassents is a positive water potential at the soil surface for 90% of each day. The criteria for the subgroup and great group classes of Wassents, using the terms sulfic, lithic, psammic, thapto-histic, fluvic, aeric, and typic, are similar to the criteria for those classes where they appear elsewhere in Soil Taxonomy (Soil Survey Staff, 2006). However, the order in which great groups of Wassents are introduced was rearranged relative to the way they appear in Aquents. In particular the Psammowassents appear higher in the key than (before) the Sulfiwassents. This change reflects the importance of soil texture in the use and management of these soils, relative to the presence of sulfidic materials (which is relatively common in estuarine subaqueous soils). The objectives in this study were to 1) to characterize the soils of Chincoteague Bay; 2) classify the soils described in Chincoteague Bay according to Soil Taxonomy; 3) classify the soils according to the proposed amendments to Soil Taxonomy; and 4) assess the impact of the proposed changes to Soil Taxonomy as reflected by the soils of Chincoteague Bay. 92 Materials and Methods Study Site Chincoteague Bay is a 19,000 ha coastal lagoon along Maryland?s eastern shore that formed as a result of sea level rise and consequent flooding of the low- lying areas following the last glacial period. Chincoteague Bay is separated from the Atlantic Ocean by a barrier island, Assateague Island, and is connected to the ocean by two inlets (Ocean City inlet and Chincoteague inlet). This coastal lagoon is relatively shallow with water depths reaching 2.5 m in the central portion of the lagoon. The average tidal fluctuations within Chincoteague Bay range from 10 to 20 cm. Chincoteague Bay is classified as a polyhaline lagoon with salinity levels ranging between 26 and 34 ppt, with the higher values occurring in the summer months (Wells and Conkwright, 1999). Parent materials of upland soils in this watershed include alluvium, aeolian sand, organic materials, and marine sediments (Soil Survey Staff, NRCS, USDA, 1997). Soil Sampling High resolution false-color infrared photography and a bathymetric map of Chincoteague Bay were used as a base maps in conjunction with data on slope, water depth, landscape shape, and proximity to other features, to delineate the subaqueous landscape units in the lagoon (Chapter 3). The high resolution orthomosaic photograph used in Figures 4-1, 4-42, and 4-43 was provided by USDA-NRCS Geospatial Data Branch in Fort Worth, TX (USDA-NRCS, 2001). Within and across the identified landforms, specific locations were chosen for sampling in order to 93 document the composition and variability within each landscape unit and to identify differences between adjacent units. The soils were accessed by boat and their locations were recorded by using a global positioning (GPS) unit. Some of the soil cores were extracted from the lagoon using 7.6 cm-diameter Al pipes that were pushed into the soil using a vibracorer mounted on a 6.4 m (21 ft) pontoon boat. Before extraction of the core, the distance from the top of the pipe to the top of the soil surface (outside the pipe) and the distance from the top of the pipe to the top of the soil sample (inside the pipe) was measured to estimate the amount of compaction of the profile within the pipe. The cores were extracted and then split in half using a circular saw while on the boat. Soils were also extracted from the lagoon using a McCauley peat sampler by sampling in 50 cm increments from the soil surface. Using a vibracorer or a McCauley peat sampler, cores from 146 pedons (Figure 4-1) were extracted from the bay bottom and morphological descriptions were completed according to standard procedures (Schoeneberger et al., 2002). Soil horizons were separated based on changes in color, texture, n value, presence or absence of shells and organic fragments, where changes were recognizable and deemed to be pedologically significant. Abbreviated descriptions were collected at an additional 17 locations (Figure 4-1). Eighty-six of the pedons were sampled for possible laboratory analysis and were placed into plastic bags, sparged with N 2 gas, stored on ice, and then placed into a freezer at the end of the day. Samples were kept frozen until laboratory analyses were completed. During the process of making soil descriptions, the presence or absence of H 2 S gas and the intensity of its aroma were also noted for each horizon. If the 94 intensity was strong, H 2 S gas could be recognized during normal description protocols. But, if the intensity was weak or could not be detected, a small sample was placed into a plastic bag with approximately 1 to 2 ml 10% HCl and sealed. After 2 to 5 minutes was allowed for reaction, the sample in the bag was again checked for the presence of H 2 S gas. These tests allowed us to qualitatively check for the presence or absence of acid volatile sulfides in the soil profile. Each horizon was placed into three classes for H 2 S gas aroma: none (no odor); weak (odor after adding 10% HCl); or strong (odor recognized without adding 10% HCl) (Darmody et al., 1977; Darmody and Fanning, 1977). Laboratory Analysis Pedons representative of each landform were analyzed for a variety of chemical, physical, and mineralogical analyses including pH, sulfide content, electrical conductivity, particle-size distribution, carbon, and mineralogy. Soil pH was measured on a freshly thawed sample, using an approximate ratio of soil to distilled water of 1:1. These soil samples were then placed into 1cm deep Petri dishes and were incubated at room temperature under a moist, aerobic environment for 13 to 24 weeks. Soil pH measurements were recorded each week for the first eight weeks and then every two to three weeks for the remainder of the time. Acid-volatile sulfides (AVS) and chromium reducible sulfides (CRS) were determined using the procedure of Cornwell and Morse (1987). Frozen samples were handled under a nitrogen atmosphere in a glove-bag prior to analysis. Electrical conductivity was measured for each horizon on a freshly thawed sample using a 1:5 (by volume) ratio of soil to distilled water. The moisture content 95 Figure 4-1. Locations of full subaqueous soil profile descriptions and brief observations and notes collected in Maryland?s portion of Chincoteague Bay. Locations were selected to determine the composition and variability within landscape units and to identify differences between adjacent units. 96 was also determined on these samples at the same time. Electrical conductivity was measured using YSI Model 32 Conductance Meter (Yellow Springs Instrument Co, Inc., Yellow Springs, OH). The electrical conductivity measurements were converted from ?mhos cm -1 to mg L -1 by multiplying by a conversion factor of 0.64 (SWAT Laboratory, 2006). A portion of the sample was air dried, crushed, and sieved (<2 mm) for particle-size and carbon analyses. Particle-size analyses were performed by a modified pipette method (Kilmer and Alexander, 1949) where prior to the analysis the samples were dialyzed to remove salts. After the sands were removed by sieving, an aliquot of the sample was collected while being stirred to be able to calculate the amount of total silt and clay in the sample. Bulk density was determined for pedons collected using the McCauley sampler (which provides an intact half core with a known volume) for each horizon by dividing the sample volume by the oven-dry weight (105?C) of the sample. For pedons collected using the vibracorer method (generally sandier soils), bulk density was estimated by packing a container of known volume with freshly thawed soil. The oven dry weight was obtained for these samples and used to estimate the bulk density. For carbon determination, dried soil samples were ground to pass through a 140 mesh (106 ?m) sieve. Total carbon was determined by combustion at 990?C with a LECO CHN-2000 Analyzer and a burn time of 174 sec (LECO Corp., St. Joseph, MI), which is higher and longer than the normal operating temperature of 900?C to help ensure full combustion of carbonates. For organic carbon determination a portion of the sample (1 g) was placed into a 50 ml beaker to which approximately 5 to 10 ml 97 of a 5% sulfurous acid solution (H 2 SO 3 ) was added to dissolve any carbonates from the soils (Piper, 1942). Once reaction with the sulfurous acid ceased, the samples were placed into an evacuated desiccator containing NaOH pellets to remove water and excess sulfurous acid. Once all of the H 2 SO 3 was removed, samples were placed into a 105?C oven to dry; the samples were then reground to pass through the 140 mesh sieve (Nelson and Sommers, 1982). The carbon content of these treated samples was measured by combustion at 990?C. Calcium carbonate-carbon was calculated as the difference between the total carbon and organic carbon (Nelson and Sommers, 1982). The presence or absence of carbonates was further confirmed for each sample by observing the soil under a 10x dissecting microscope when adding a few drops of 10% HCl. Five effervescence classes were used to indicate the intensity of the reaction observed under the microscope: non-effervescent (NE) ? no reaction; very slightly effervescent (VS) ? one or two bubbles; slightly effervescent (SL) ? few bubbles; strongly effervescent (ST) ? many bubbles; and violently effervescent (VE) ? low foam (Schoeneberger et al., 1998). The n value was estimated in the field by squeezing a portion of the soil and estimating how the soil flows through one?s fingers. In the field four classes were used for n value estimations: <0.7 ? non fluid, soil does not flow through fingers; 0.7- 1.0 ? slightly fluid, soil flows through fingers with some difficulty; >1.0 ? moderately fluid, soil flows easily through fingers; and >>1.0 ? very fluid, soil flows very easily through fingers. The n value was also calculated using the following equation developed by Pons and Zonneveld (1965): n = ((A-0.2*R)/(L+3H)) [Eq. 1] 98 where A is the percentage of water at field condition; R is the percent of silt plus sand; L is the percent clay; and H is the percent organic matter (%OC*1.724). Radiocarbon analysis of several buried organic horizons was performed by Beta Analytical, Inc. in Miami, Florida using a standard radiometric analysis with acid wash pre-treatment. Mineralogy was assessed for selected sandy and loamy soils using grain counting methods (Balduff and Rabenhorst, 2007) while x-ray diffraction techniques were used for analysis of silt and clay for finer textured soils (Burt et al., 2004). Grain Size Distribution Particle-size data collected for 188 samples was divided into seven classes (vcS, cS, mS, fS, vfS, Si, and C). The median particle size, mean particle size, and sorting coefficients were determined graphically by plotting the percentage of each separate creating a cumulative frequency plot. The sorting coefficient developed by Trask (1932) expressed sorting as S o = (?75-?25)/1.35 [Eq. 2] where ?75 and 25 are obtained from the cumulative frequency plots. Descriptive classes of Trask assigned from numerical values of S o are: excellent- 0 to 0.58; well- 0.58 to 1.32; moderately well- 1.32 to 2.0; and poorly- > 2.0. Folk (1974) expressed sorting as ? i = [(?84-?16)/4] + [(?95-?5)/6.6] [Eq. 3] where ?95, 84, 16, and 5 are obtained from the cumulative frequency plots. Soils with a sorting coefficient of 0 to 0.35 were considered to be very well sorted, 0.35 to 0.50 well sorted, 0.50 to 0.71 moderately well sorted, 0.71 to 1.00 moderately sorted, 99 1.00 to 2.00 poorly sorted, 2.00 to 4.00 very poorly sorted, and >4.00 extremely poorly sorted (Leeder, 1982). Results and Discussion Characterization of Subaqueous Soils Subaqueous soils are similar to young alluvial soils that form on floodplains. These soils are characterized as having a well developed A horizon overlying C horizons that maintain many characteristics related to their environment of deposition. Subaqueous soils, like alluvial soils, are not described as stratigraphic geologic units due to pedogenic processes which alter these materials leading to the creation of soils. These processes include the addition of organic matter, biogenic CaCO 3 , bioturbation from benthic biota, and chemical transformations of sulfur and iron in anoxic sediments, all of which differentiate surficial sediments into soil horizons (Demas and Rabenhorst, 1999). In the field, hand texturing was used to determine the texture class of each horizon as recorded in the profile descriptions. It is more difficult to determine the correct texture of these samples compared to texturing subaerial soils due to the excess water in the subaqueous samples. Due to the difficulty in texturing, there was some uncertainty regarding the accuracy of our field data. Therefore, to assess the accuracy of field textures and their potential use in classifying soils, particle size data were plotted by groups based on field textures for 188 horizons. The field textures as compared to particle size classes are presented in Table 4-2. This table was used to help interpret the remaining field textures for pedons that were not analyzed in the laboratory. Generally our field textures were more accurate when the soils were sandy 100 textured (sand, fine sand, loamy sand, loamy fine sand, sandy loam, and fine sandy loam) than when finer textured (Figure 4-2, 4-3, and 4-4). The sandy textured soils with a fine size modifier tended to be described in the field as a class finer than what was determined by particle-size analysis (Figure 4-3). For example, most soils that were textured in the field as loamy fine sand were in fact fine sand and those that were described as fine sandy loam were in fact mostly loamy fine sand (by particle- size analysis). The finer textured soil horizons (loams, clay loams, silty clay loams, silty clays and clays) tended to be described in the field as one class finer than the particle-size data showed them to be (Figure 4-2 and 4-4). For example, soils that were described in the field as silty clays were mostly silty clay loams and those described in the field as clay were mostly loams. However, the horizons in the field described as loams were in fact mostly loams. Soils that tended to be clay loams in the field tended to be coarser than we thought and laboratory analyses showed that these horizons were usually in the loam or sandy loam class. The horizons described in the field as silty clay loam tended to have more sand then we thought. Those samples tended to lie along the borders of the silty clay loam, clay loam, and loam classes. This probably would not impact the classification of the soils at the family class level because the majority of the sand is fine or very fine. The very fine sand fraction in these soils was included in the coarse silt fraction (as required by Soil Taxonomy). So, samples placed into the silty clay loam class in the field were accurate for our classification purposes. In conclusion the texture data collected in the field for profiles that were not analyzed in the lab are still usable for classification purposes when keeping in mind the trends and utilizing Table 4-2 to determine a 101 Table 4-2. Field textures compared to textures from particle-size data for selected horizons collected in the summers of 2004 and 2005 in Chincoteague Bay. Textures Based on Particle-Size Analysis n S fS LS LfS SL fSL vfSL L SiL CL SiCL SiC Field Textures ---------------------------------------------%------------------------------------------------ 15 S 87 13 9 fS 100 16 LS 38 56 6 10 LfS 70 20 10 26 SL 4 35 31 19 12 7 fSL 43 43 14 1 SC 100 18 L 11 11 28 6 33 11 6 SiL 17 50 33 3 CL 33 33 33 16 SiCL 13 18 19 50 49 SiC 2 2 14 8 12 45 16 12 C 8 8 58 8 17 102 Figure 4-2. A. Particle-size data for soil horizons that were field textured as sands. B. Particle-size data for soil horizons that were field textured as loamy sands. C. Particle-size data for soil horizons that were field textured as sandy loams. D. Particle-size data for soil horizons that were field textured as loams. 103 Figure 4-3. A. Particle-size data for soil horizons that were field textured as fine sands. B. Particle-size data for soil horizons that were field textured as loamy fine sands. C. Particle-size data for soil horizons that were field textured as fine sandy loams. 104 Figure 4-4. A. Particle-size data for soil horizons that were field textured as clay loams. B. Particle-size data for soil horizons that were field textured as clays. C. Particle-size data for soil horizons that were field textured as silty clay loams. D. Particle-size data for soil horizons that were field textured as silty clays. 105 more accurate assessment of the textures. The particle-size distributions of all 188 subaqueous soil horizons analyzed are shown in Figure 4-5 where it can be seen that all the subaqueous horizons analyzed plot within a very narrow band. The unusual nature of this grouping can be seen when it was compared to the plots of particle-size data of subaerial soil horizons analyzed in the Maryland coastal plain (Figure 4-6). To try to explain the unusual nature of these particle-size data we examined the cumulative frequency plots for all analyzed pedons in Chincoteague Bay and made comparisons to several subaerial soils located in Wicomico County and Worcester County, Maryland. The cumulative frequency graphs provide general conclusions about the grain size distribution in a sample. Krumbein (1939) studied the sediments and depositional environments within Barataria Bay, LA, which is a tidal lagoon. Based on the sediment distribution of 98 samples, he was able to distinguish five different groups of sediments within the environment (Figure 4-7). The five types of sediments he identified were Type I: beach sands and shallow water sands in the zone of breakers with a median value of ? = 3; Type II: predominately sandy, but with some silt and clay, and occurred in channels where currents were stronger with a median value of ? = 3.3; Type III: composed of 50% sand and occurred on the border of channels and covered locally large areas with moderately deep water with a median of ? = 4; Type IV: predominantly silty with an average of 25% sand, located in the basin with a median of ? = 4.7; and Type V: contained the finest sediments with highest organic contents and a median ? = 6; were located along the fringe of low islands and in areas farthest from the currents. The cumulative frequency graphs for the sediments in 106 Figure 4-5. Distribution of particle-size data for 188 subaqueous soil horizons analyzed in this study. 107 Figure 4-6. Distribution of particle-size data for subaerial soils found throughout Maryland (University of Maryland Pedology Lab, 2007). Each marker represents a different county in Maryland. 108 Figure 4-7. Cumulative frequency curves from sediment samples collected from Barataria Bay, LA, which is a tidal lagoon. These curves represent five different depositional environments found within Barataria Bay (From Krumbein, 1939). The five types of sediments are Type I: beach sands and shallow water sands in the zone of breakers with a median value of ? = 3, Type II: predominately sandy, but with some silt and clay, and occurs in channels where currents are stronger with a median value of ? = 3.3, Type III: composed of 50% sand and occur on the border of channels and cover locally large areas with moderately deep water with a median of ? = 4, Type IV: predominantly silty with an average of 25% sand, located in the basin with a median of ? = 4.7, and Type V: contains the finest sediments with highest organic contents and a median ? = 6; are located along fringe of low islands and in areas farthest from the currents. 109 Chincoteague Bay are very similar to Krumbein?s curves of the five types of sediments, although the type of curve is not always consistent with depth through the profile. The soils that were located on the storm-surge washover fan flats, storm-surge washover fan slopes, and paleo-flood tidal delta (Figure 4-8) generally show Type I curves. These are high-energy environments impacted by waves, tidal currents, and storm events, which winnows out the finer sediments from these areas. Soils found on the storm-surge washover fan slopes, barrier coves, and shoal landforms generally show Type II cumulative curves, which are generally sandy with small quantities of silt and clay (Figure 4-9). The quiet lagoon bottom and fluviomarine bottom sediments have curves most like Krumbein (1939) Type III and IV cumulative curves, reflecting a dominance of finer textured sediments (Figure 4-10). The mainland cove and submerged wave-cut headlands have cumulative frequency curves shaped similarly to the Type II, III, and IV curves which highlight a broader range of particle-sizes found on these landforms (Figure 4-11). The cumulative frequency curves for several horizons ? Ab, BAb, and Btgb ? had a bimodal distribution, which can be attributed to weathering or clay formation within the profile before submergence. The cumulative frequency curves from subaerial soils have shapes similar to Type II and III, but these curves also appear to be bimodal (Figure 4-12). These horizons are similar to curves we observed for horizons located below buried organic horizons, which we attributed to soil forming processes such as weathering or clay formation within a soil profile lending strength to the argument that some of the deeper horizons on the mainland side of the lagoon are in fact old subaerial soils that have been buried by younger materials. 110 Figure 4-8. Cumulative frequency curve from the storm-surge washover fan flat in Chincoteague Bay (pedon CB16). These curves are similar to the Type I and II curves described by Krumbein (1939). 111 Figure 4-9. Cumulative frequency curve from the barrier cove in Chincoteague Bay (CB52). These curves are similar to the Type II curves described by Krumbein (1939). 112 Figure 4-10. Cumulative frequency curve from the lagoon bottom in Chincoteague Bay (pedon CB18). These curves are similar to the Type III and IV curves described by Krumbein (1939). 113 The sorting coefficient of the population can provide information about a transporting agent?s ability to entrain, transport, and deposit grains of different sizes. Sorting can reflect differences in velocity and the ability of the agent to preferentially transport and deposit particular grain sizes. Sorting coefficients developed by Trask (1932) and Folk (1974) were used in this study to document the degree of sorting of the Chincoteague Bay soils and to compare these soils to subaerial soils in Maryland. Most of the soils in Chincoteague Bay are poorly or very poorly sorted based on Folk?s classification, whereas using Trask?s system the soils are normally distributed from excellent to poorly sorted (Figure 4-13). The subaerial soils of Wicomico and Worcester Counties are poorly and very poorly sorted using Folk?s classification and most are poorly sorted using Trask?s sorting coefficient (Figure 4-14). Folk?s sorting coefficient provides more detailed classes and includes more fractions to determine sorting, which broadens the range of sorting occurring in Chincoteague Bay when compared to subaerial soils of Maryland. The soils of Chincoteague Bay and the subaerial soils are both poorly sorted with some well sorted samples. Generally, the subaqueous soils are better sorted than the subaerial. The sorting coefficients and the cumulative frequency plots do not provide a definitive answer to explain why the particle-size distribution of soils from Chincoteague Bay lie in a very narrow band compared to the subaerial soils from Maryland. The presence or absence of sulfidic materials within the soil profile has important ecological and environmental ramifications and is an important criterion in the characterization of these soils. The determination of whether or not sulfidic materials were present was based on moist, aerobic incubations of the soil horizons. 114 Figure 4-11. Cumulative frequency curve from the mainland cove in Chincoteague Bay (pedon CB21). These curves are similar to the Type III and IV described by Krubein (1939). 115 Figure 4-12. Cumulative frequency curves from a subaerial soil located in Worcester County, Maryland. 116 Figure 4-13. A. Distribution of Trask sorting coefficients (1939) for soils in Chincoteague Bay. Excellent sorted ranges from 0 to 0.58, well sorted ranges from 0.58 to 1.32, moderately well sorted ranges from 1.32 to 2.0, and poorly sorted is greater than 2. B. Distribution of Folk sorting coefficients (1974) for soils in Chincoteague Bay. Very well sorted ranges from 0 to 0.35, well sorted ranges from 0.35 to 0.50, moderately well sorted ranges from 0.50 to 0.71, moderately sorted from 0.71 to 1.0, poorly sorted ranges from 1.0 to 2.0, very poorly sorted ranges from 2.0 to 4.0, and extremely poorly sorted is greater than 4.0. 117 Figure 4-14. A. Distribution of Trask sorting coefficients (1939) for soils in Wicomico and Worcester County, Maryland. Excellent sorted ranges from 0 to 0.58, well sorted ranges from 0.58 to 1.32, moderately well sorted ranges from 1.32 to 2.0, and poorly sorted is greater than 2. B. Distribution of Folk sorting coefficients (1974) for soils in Wicomico and Worcester County, Maryland. Very well sorted ranges from 0 to 0.35, well sorted ranges from 0.35 to 0.50, moderately well sorted ranges from 0.50 to 0.71, moderately sorted from 0.71 to 1.0, poorly sorted ranges from 1.0 to 2.0, very poorly sorted ranges from 2.0 to 4.0, and extremely poorly sorted is greater than 4.0. Using both classification systems most of the subaerial soils are poorly sorted compared to subaqueous soils that are better sorted. 118 The definition of sulfidic materials requires that the pH drop below 4 within eight weeks (due to the oxidation of sulfides and the generation of acid). Our hypothesis was that soil horizons that had noticeable H 2 S in the field should probably show a drop in pH below 4. However, pyritic forms of sulfides would not produce H 2 S when HCl is applied, so we only could identify monosulfides in the field. Samples with sandy textures (s, ls, or sl) tend to show a quick drop to pH below 4, which is probably due to the low buffering capacity and lack of carbonates (Figure 4-15). Samples that have loamy textures (l, sicl, cl) seem to show a slower drop in pH, presumably due to the higher buffering capacity of these soils (Figure 4-16). Therefore, we monitored the pH for a longer period of 13 to 24 weeks to better allow more time for pH to drop and thus document the presence of sulfidic materials in these soils. If soil samples contain adequate calcium carbonate to neutralize the generated acidity their moist incubation pH values do not drop below pH 4 even after 24 weeks of monitoring (Figure 4-17). These samples had pH values that stayed near 7-8, which indicated the presence of excess carbonate. Based on these observations, the requirement for a drop in pH below 4 to occur within eight weeks might not adequately identify the presence of sulfidic materials in at least some of these soils. The samples that take longer than eight weeks to show a drop in pH should also be recognized as having sulfidic materials within their profiles. The majority of our samples (78%) showed a drop in pH below 4 within 25 weeks. Table 4-3 shows the length of time that samples needed for pH to drop below 4. A small portion (20 %) of the samples required only four weeks for pH to drop below 4, but only 57% of the samples required eight weeks for pH to drop below 4. By doubling the length of time, 119 Figure 4-15. Moist incubation pH data for a sandy textured soil (Core CB01). In all horizons, except the surface, pH drops below 4 within eight weeks. 120 Figure 4-16. Moist incubation pH data for a loamy textured soil profile (Core CB18). None of the horizons showed a drop in pH within eight weeks, but they did begin to drop below 4 within 11 to 15 weeks. 121 Figure 4-17. Moist incubation pH data for a loamy textured soil profile that contains biogenic calcium carbonate in several horizons (Core CB141). Note the samples with excess carbonates maintained a pH around 7-8. 122 Table 4-3. The length of time for 163 samples incubated under moist aerobic conditions to drop below a pH of 4. Only 51% of these samples that would eventually show a drop in pH to below 4 did so within the prescribed eight weeks. Length of time to drop below pH 4 Number of samples ? % of Samples that eventually show a drop in pH<4 4 weeks 25 (16%) 20 8 weeks 73 (45%) 57 12 weeks 104 (64%) 81 16 weeks 117 (72%) 91 20 weeks 125 (77%) 98 24 weeks 128 (78%) 100 ? 46 samples were only incubated for 16 weeks 123 pH dropped below 4 in 91 % of the samples. Therefore, we recommend monitoring the pH of these soils longer than the specified eight weeks if the goal is to identify the presence or absence of sulfidic materials in these environments. The moist incubation pH data provides information regarding the presence or absence of sulfidic materials within the soil profile, but it does not provide information regarding the type or amount of sulfide bearing minerals within the soil. In the field we documented the presence or absence of H 2 S and the intensity its aroma. When samples did not have a noticeable aroma we added a small quantity of 10% HCl to the sample, which allowed us to qualitatively check for the presence of acid volatile sulfides in the soil profile. The quantities of acid volatile sulfides (monosulfides) and chromium reducible sulfides (disulfides) were determined on several selected profiles from three major landforms in Chincoteague Bay (mainland cove, lagoon bottom, and storm- surge washover fan flat). The acid volatile sulfide and chromium reducible sulfide data are presented in Table 4-4. The acid volatile sulfide concentration was very low in these profiles, even when the chromium reducible sulfide concentrations were substantial. The distribution of chromium reducible sulfide (disulfides) in these selected pedons is shown in Figure 4-18. The lowest pyrite concentrations are in the sandy soils that occur on the storm-surge washover fan flats. These areas likely have lower pyrite concentrations due to lower organic carbon and lower iron inputs compared to the other sites. The highest pyrite values occurred in the buried organic horizons located in the mainland cove. The mainland coves provide optimal conditions for the formation of pyrite, which include a large source of oxidizable carbon and a supply of iron sorbed to fine mineral 124 Table 4-4. Acid volatile sulfide (monosulfides) and chromium reducible sulfide (disulfides) concentrations from the storm-surge washover fan flat (CB01), lagoon bottom (CB18 and CB58), barrier cove (CB52) and mainland cove (CB11). Sample Acid Volatile Sulfides g kg -1 Chromium Reducible Sulfides g kg -1 Organic Carbon g kg -1 Time for pH to drop below 4 (days) Final pH CB01 A, 0-14 cm 0.00 0.08 0.76 nd ? 4.8 CB01 Cg1, 14-76 cm 0.04 0.16 0.44 14 3.3 CB01 Cg2, 76-103 cm 0.00 1.03 0.82 21 3.1 CB01 Cg3, 103-170 cm 0.00 0.39 1.56 49 2.9 CB01 Cg4, 170-210 cm 0.06 1.81 3.09 35 2.8 CB11 A2, 2-12 cm 0.03 1.64 7.02 77 3.1 CB11 Cg1, 12-36 cm 0.03 13.31 19.56 35 2.6 CB11 Cg2, 36-56 cm 0.06 12.34 42.17 35 2.5 CB11 Oab1, 56-83 cm 0.00 27.52 157.00 21 2.3 CB11 Oab2, 83-109 cm 0.00 47.93 212.20 49 2.6 CB11 2Ab, 109-115 cm 0.12 4.48 71.30 --- ? 5.2 CB11 2Cgb, 115-122 cm 0.05 0.79 22.32 --- ? 6.2 CB18 A, 0-8 cm 0.02 2.33 nd nd nd CB18 Cg, 8-50 cm 0.02 6.30 15.23 105 3.2 CB18 Cg, 50-100 cm 0.05 6.41 12.37 105 3.2 CB18 Cg, 100-150 cm 0.04 6.38 13.89 --- ? 4.8 CB18 Cg, 150-200 cm 0.15 6.61 11.30 77 3.1 CB18 Cg, 200-250 cm 0.06 6.29 13.09 77 2.9 CB52 Cg1, 10-21 cm 0.00 4.02 9.04 77 2.63 CB52 2Cg2, 21-39 cm 0.00 5.96 11.57 77 2.60 CB52 2Cg3, 39-59 cm 0.04 5.95 14.14 63 3.03 CB52 2Cg4, 59-86 cm 0.07 5.09 16.95 77 2.80 CB52 2Cg5, 86-115 cm 0.21 4.18 9.77 112 3.60 CB52 2Cg6, 115-138 cm 0.08 4.77 6.13 --- ? 4.15 CB58 A2, 3-14 cm 0.05 1.01 2.18 --- ? 7.59 CB58 Cg1, 14-37 cm 0.02 3.16 3.96 112 3.75 CB58 Cg2, 37-106 cm 0.04 4.35 3.38 140 3.11 CB 58 2Cg3, 106-162 cm 0.02 7.54 10.31 112 3.12 ? no data were collected for these samples ? a drop below pH 4 within 16 weeks did not occur in these samples ? a drop below pH 4 within 25 weeks did not occur in these samples 125 Figure 4-18. Distribution of chromium reducible sulfides (disulfides) with depth of soils on the storm-surge washover fan flat (CB01), lagoon bottom (CB11 and CB58), barrier cove (CB52), and mainland cove (CB11). 126 sediments. The n value is an important criterion in classifying mineral soils at the great group and series level. The n value was estimated in the field by squeezing a portion of the soil and estimating how much of the soil flows through the fingers. The estimation of the field n value provided information regarding the bearing strength of the soil, the lower the n value the higher the bearing capacity. However, the calculated n value (Eq. 1) characterizes the relationship between the water content, percentage of sand and silt, percentage of clay, and organic matter. We calculated the n value for 163 samples for which we obtained the necessary inputs. Samples with more than 95% sand were not used in analysis because the very low clay contents resulted in deceivingly high values and furthermore extremely sandy soils are generally thought to have low n values. Therefore we examined the soils in two groups <80% sand or 80 to 95% sand. The frequency distribution for the calculated n values for these two groups of soils is shown in Figure 4-19. Both groups generally had n values greater than 1. However, we anticipated that the soils with 80 to 95% sand would mostly have n values less than 1. Usually, n values are not calculated but rather are estimated in the field by squeezing a handful of soil. The frequency of the field estimated n values for soils with 80 to 95% sand and <80% sand are shown in Figure 4-20. The soils with sandy textures (fS, LS, or LfS) mostly had field estimated n values less than 0.7 indicating that these soils are non-fluid. These soils were located on the storm-surge washover fan flat, storm-surge washover fan slope, and paleo-flood tidal delta landforms. The loamy textured soils (fSL, SL, or L) mostly had field estimated n values of 0.7-1. These soils are slightly fluid and were mostly found 127 Figure 4-19. The frequency distribution of the calculated n values for 163 samples from Chincoteague Bay. The samples with more than 95% sand were not included because the values were erroneous. 128 Figure 4-20. The frequency distribution of n values estimated in the field for 163 samples from Chincoteague Bay. Note the sandy textured soils (fs, ls, or lfs) mostly had n values less than 0.7 and the finer textured soils (sicl, sic, or c) had n values greater than 1. 129 on the storm-surge washover fan slopes, barrier coves, and barrier side of the lagoon bottom. The finer textured soils (SiCL, SiC, or C) mostly had field estimated n values greater than 1. These soils were moderately to very fluid which indicates that these soils would have a low bearing capacity and mostly located on the lagoon bottom, mainland cove, submerged wave-cut headland, barrier cove, and fluviomarine bottom landforms. A comparison between field estimated n values and calculated n values (from Eq. 1) are presented in Figure 4-21. According to Soil Taxonomy the ?critical n value of 0.7? should be approximated closely in the field by using the squeeze test. Using the data obtained from the soils in Chincoteague Bay the calculated n values did not correlate with the field estimated n values for the sandier textured soils (>50% sand), but were better correlated for the finer textured soils (<50% sand). The field estimated n value provided a more accurate description of the fluidity and bearing capacity of the soil. Salinity data for the soils analyzed in this study are presented in Figure 4-22 and Figure 4-23. The subaqueous soils of Chincoteague Bay had porewater salinity ranges from 16 to 37 ppt in the upper portion of the soil profile. Salinity distributions of pedons from the fluviomarine bottom, lagoon bottom, storm-surge washover fan slopes, storm-surge washover fan flats, paleo-flood tidal delta and barrier coves (eastern side of the bay) are shown in Figure 4-22. The salinity distributions within pedons located in the eastern portion of the bay remained high with depth and generally centered around 26 to 34 ppt, which is the salinity of the bay water. Several horizons within these pedons had salinity values greater than 36 ppt, which seem erroneously high, since one would think that the salinity should not be greater than 130 Figure 4-21. Comparison of the field estimated n values and the calculated n values for 163 samples collected in Chincoteague Bay. The field estimated n values for the sandier soils (>50% S) did not correlate well with the calculated n values, but the finer textured soils (<50% S) were better correlated. The field estimated n value provided a more accurate description of the fluidity and bearing capacity of the soils. 131 Figure 4-22. Porewater salinity for soils located on the storm-surge washover fan flats (CB01 and CB56), barrier coves (CB10), and lagoon bottom (CB18 and CB79). The salinity levels generally do not show a trend with depth and do not decrease below 20 ppt. Note the dashed lines represent the salinity range found within Chincoteague Bay. 132 the overlying water. The higher salinity values might be attributed to experimental errors or possibly even to exposure of the sample to an oxygenated environment which may have caused oxidation of sulfide bearing minerals and the formation of sulfate salts (although every precaution was taken during the sampling process to preclude oxidation of the samples). However, higher salinities have been reported in groundwater underlying Assateague Island. It was suggested that during the summer evaporation of seawater in barrier salt marshes produced the brine that sinks through the groundwater and flows along the silt confining layer until it pools in coarser old inlet channel sediments (Norton and Krantz, 2004). Salinity distributions of pedons located close to the mainland (within the mainland cove and submerged wave-cut headland landforms) are shown in Figure 4-23. Salinity distributions of pedons located near the mainland tended to show a systematic decrease with depth. The salinity levels at the bottom of these pedons drops as low as 2 ppt, which is far different from the overlying sea water. The lower salinity values associated with these areas are likely the result of groundwater discharge into the bay from the surrounding watershed (Dillow et al., 2002). Carbon Distribution in Subaqueous Soils Total carbon, organic carbon, and calcium carbonate contents were determined for 51 pedons sampled in Chincoteague Bay. Following the methodology of Piper (1949) calcium carbonate was initially considered to be equal to the difference in carbon measured by dry combustion on paired samples that had, and had not, been treated with H 2 SO 3 (sulfurous acid). It was observed, however, that even 133 Figure 4-23. Porewater salinity contents for soils located near the mainland in the mainland cove and lagoon bottom landforms. CB09 is closest to the mainland (120 m) and CB97 is farthest from the mainland (1200 m). Salinity in the near surface horizons approached that of the overlying bay water, but decreases with depth. The decrease in porewater salinity levels with depth was attributed to groundwater influx into the bay. Note the dashed lines represent the salinity range found within Chincoteague Bay. 134 samples that showed no evidence of effervescence when HCl was applied, still showed a measurable difference between carbon in the treated and untreated samples. To investigate this possibility, 11 samples from acid subaerial soils without carbonates were evaluated. Carbon measured by dry combustion before and after treatment with H 2 SO 3 is shown in Figure 4-24. Approximately 7.5% of the organic carbon present in the samples appeared to be oxidized by the H 2 SO 3 treatment. For the subaqueous soils in this study, we identified the presence or absence of carbonates in selected pedons by looking for a reaction with 10% HCl when observed under a 10x microscope. Those samples that did not react at all were considered free of carbonates. To further assess the oxidation of organic carbon by sulfurous acid, fifty-three non-effervescent samples were analyzed for carbon before and after treatment with H 2 SO 3 . The data are shown in Figure 4-25. On average, 4.5% (SD 3.1%) of the organic carbon in the samples was oxidized by the H 2 SO 3 treatment. Using these data, the organic carbon content in soils that contained calcium carbonate was corrected and calcium carbonate levels were proportionally adjusted to remove this systematic error. The samples described (under the microscope with HCl acid) as having very slight effervescence had calcium carbonate quantities that ranged from 0.0 to 17.0 g kg -1 (mean 3.2). Samples described as having slight effervescence had calcium carbonate quantities that ranged from 0.0 to 30.4 g kg -1 (mean 7.4). Samples with strong or violent effervescence had significantly higher levels of calcium carbonate that ranged from 18.3 to 370.0 g kg -1 (mean 89.6). Shell fragments were described in 123 soil profiles (84%), with quantities ranging from 1 to 80% by volume (using visual estimation). Larger fragments and 135 Figure 4-24. Samples collected from 11 acid non-calcareous subaerial soil samples that were treated with 5% sulfurous acid. The organic carbon contents of the untreated samples and treated samples differed by an average of 7.5% (SD 3.4%). This difference indicated that the sulfurous acid treatment oxidized a portion of the organic carbon. 136 Figure 4-25. Samples collected from non-effervescent subaqueous soils were treated with 5% sulfurous acid. The organic carbon contents of the untreated samples and treated samples differed by an average of 4.5% (SD 3.1%). This difference indicated that the sulfurous acid treatment oxidized a portion of the organic carbon. 137 intact shells could be identified as gastropods, oysters, mussels, razor clams, and hard clams. Although shells were observed in the majority of the pedons, the quantity of calcium carbonate contributed to the soils by these organisms was generally low. The calcium carbonate distributions for four pedons located on the storm surge washover fan flats are shown in Figure 4-26. Calcium carbonate distributions for finer textured soils located on the lagoon bottom are shown in Figure 4-27. The coarser textured soils and the finer textured soils throughout the bay contained small quantities of calcium carbonate. The addition of biologic carbonates to these soils was generally a result of in situ benthic organisms. The coarser soils had calcium carbonate contents throughout the profiles compared to the finer textured soils that tended to have biogenic calcium carbonate only in the upper horizons. These coarser textured areas tend to be better habitats for bivalves (filter feeders) compared to finer textured soils (Rhoads and Young, 1970). However, this does not account for the shells found within the finer textured soils. Several pedons located in the lagoon bottom contained large quantities of shells and are presented in Figure 4-28. The shells in these horizons were usually broken and located in bands throughout the profile, which indicated that these shells were deposited during a storm event rather than in situ. Along the mainland side of the bay, 26 pedons contained buried organic horizons with upper boundary depths ranging from 18 to 198 cm and the thickness of these horizons ranged from 9 to 64 cm. The organic carbon distributions for six pedons that contain buried organic horizons are shown in Figure 4-29. These profiles contain the highest organic carbon contents within Chincoteague Bay. The organic carbon distributions for six pedons located on the lagoon bottom are shown in 138 Figure 4-26. Calcium carbonate distributions of select pedons located on the storm- surge washover fan flat landform. These sandy soils have low quantities of calcium carbonate throughout the profile. 139 Figure 4-27. Calcium carbonate distributions of select pedons located on the lagoon bottom landform. These finer textured soils have low quantities of calcium carbonate throughout the profile. 140 Figure 4-28. Calcium carbonate distributions of select pedons located on the lagoon bottom landform. These finer textured soils have high quantities of calcium carbonate within the upper 100 cm of the profile. The biogenic shells in these horizons were broken and located in bands which indicate that these shells may have been transported to these areas rather than from in situ organisms. 141 Figure 4-29. Organic carbon distributions of select pedons located on the mainland cove and submerged wave-cut headland landforms. Three pedons (CB11, CB21, and CB124) contained buried organic horizons within 100 cm of the soil surface. The remaining pedons (CB26, CB97, and CB136) contained buried organic horizons located deeper than 100 cm below the soil surface. 142 Figure 4-30. These pedons show an irregular organic carbon distribution with depth. The organic carbon distributions for four pedons located on the storm-surge washover fan flat are shown in Figure 4-31. These sandy soils had the lowest organic carbon contents within Chincoteague Bay. The surface horizons of the subaqueous soils had elevated C levels (1 to 24 g kg -1 ) indicating an accumulation of C within these horizons, which is similar to subaerial surface horizons. Most of these profiles showed irregular distributions of organic carbon with depth. These irregular changes occurred due to the presence of buried organic horizons or reflected changes in texture related to changes in depositional environments. The C distributions within these soil profiles are not unlike those of alluvial soils located on floodplains in terrestrial environments. The finer textured soils occurred in low-energy environments that are conducive to the accumulation of organic materials compared to the high-energy environments where the sandy soils are located. Within the upper meter of the soil, the organic carbon content of individual horizons ranged from 0.17 to 212.20 g kg -1 . The lowest values occurred in sandy textured horizons and the highest values in buried organic horizons. The pedons were grouped by landforms and the quantity of organic carbon stored in the upper 1 m of the soil is presented in Table 4-5 (data for individual pedons are located in Appendix D). Soils in the mainland coves and submerged wave-cut headland landforms have the highest quantity (5 to 34 kg m -2 ) of carbon stored in the upper 1 m largely because they have buried organic horizons within the upper 1 m of the soil surface. The lagoon bottom, fluviomarine bottom, and barrier cove landforms have moderate quantities (4 to 21 kg m -2 ) of carbon in the upper 1 m. These landforms are low- 143 Figure 4-30. Organic carbon distributions of select pedons located on the lagoon bottom landform. These pedons display irregular carbon distribution with depth. Pedon CB58 is located on the barrier island side of the lagoon bottom and the upper portion of the soil formed in sandy barrier island sediments and the deeper portion of the soil formed in finer textured lagoon bottom sediments. 144 Figure 4-31. Organic carbon distributions of select pedons located on the storm-surge washover fan flat landform. These soils are sandy and have lower organic carbon contents than finer textured soils. Pedon CB45 has an irregular increase in organic carbon with depth. The upper portion of this soil formed in sandy barrier island sediments and the lower portion of the soil formed in finer textured sediments. 145 Table 4-5. Quantities of organic carbon stored in the upper 1 m of the soil within various landforms described in Chincoteague Bay. Landform N Avg. Organic Carbon Content kg m -2 to a depth of 1 m Range of Organic Carbon Content kg m -2 to a depth of 1 m Storm-surge Washover Fan Flat 4 2.2 0.7-3.5 Storm-surge Washover Fan Slope 2 2.8 2.1-3.4 Paleo-flood Tidal Delta 1 3.6 Barrier Cove 3 9.8 4.0-16.8 Shoal 1 15.6 Lagoon Bottom 18 12.3 3.5-21.7 Fluviomarine Bottom 6 9.0 4.5-10.7 Mainland Cove 10 7.5 5.2-10.6 Mainland Cove with organic horizon within 1m 1 34.2 Submerged Wave-cut Headland 3 8.8 7.4-10.6 Submerged Wave-cut Headland with organic horizon within 1m 3 23.1 16.8-30.1 146 energy depositional environments that tend to accumulate organic matter. The lowest quantities (0.7 to 3.6 kg m -2 ) of organic carbon stored were found in soils located on the storm-surge washover fan flats, storm-surge washover fan slopes, and paleo-flood tidal delta landforms. These landforms are high-energy environments, and the amount of carbon stored in these soils is decreased by the winnowing action of the waves and currents. The amount of organic carbon stored within the upper 1 m of the soils in Chincoteague Bay, MD was similar to the organic carbon stored (6.7 to 17.7 kg m -2 ) in the subaqueous soils in Taunton Bay, ME (Jespersen and Osher, 2007). However, the extremely sandy soils located on the storm-surge washover fan flats in Chincoteague Bay had lower values (<3.6 kg m -2 ) than any of the soils in Taunton Bay, ME. In Chincoteague Bay, the soils that stored the highest organic carbon (16.8 to 34.2 kg m -2 ) were located in the mainland coves and submerged wave-cut headlands. These soils stored greater quantities of organic carbon due to the presence of organic horizons within the upper 1 m of the pedon, whereas in Taunton Bay the buried organic horizons were located deeper than 1 m and were not included in the organic carbon storage estimates. The subaqueous soils in Chincoteague Bay had carbon storage values that ranged between values reported for the poorly drained Othello soil series (6.3 kg m -2 ) and the very poorly drained Sunken soil series (18.1 kg m -2 ) located on the Delmarva Peninsula (Rabenhorst, 1995). Osher and Jespersen (2006) used stable carbon isotope data to identify that the majority of the organic carbon stored in estuary soils of Taunton Bay, ME, was fixed by estuary biota and as distance from the shore increased the content of terrestrial 147 organic matter decreased in the soils supporting that the carbon in these soils were produced in situ. These results contradict the belief that the organic carbon stored in estuarine systems is primarily transported from the surrounding watershed by surface water rather than in situ production. The carbon storage data from these studies may be an important missing component in the global carbon storage estimates. Classification Using Current Soil Taxonomy Of the 146 subaqueous soil profiles described, 144 were classified in the Entisols soil order (Soil Survey Staff, 2006). That portion of the classification hierarchy used for classification of subaqueous soils using the current classification reduction (such as chroma < 2 or positive reaction to ?,? dipyridil). All of 144 profiles in the Entisols were classified within the suborder of Aquents. In the next (Soil Taxonomy) is shown in Table 4-6. The two profiles which were not Entisols had buried organic horizons close enough to the soil surface to be classified as Histosols. The Aquents suborder requires saturation for extend periods and evidence of level of Soil Taxonomy (great group), the order in which the great groups key out is based on the perceived significance of the soil properties. Two great groups of Aquents were recognized in Chincoteague Bay, being (in descending hierarchal order), Sulfaquents and Hydraquents. All but one of the Aquents keyed out into the Sulfaquents great group. Sulfaquents are Aquents that have sulfidic materials in any subhorizon within the upper 50 cm of the soil profile. A single Aquent profile (CB50) keyed out as a Hydraquent, due to the absence of sulfidic materials within the upper 50 cm of the soil surface. Four subgroups of Sulfaquents were used to classify the soil profiles. 148 Table 4-6. That portion of Soil Taxonomy (2006) used in the classification of 146 subaqueous soils in Chincoteague Bay. Note that sulfi great groups of Saprists and Aquents are distinguished by the presence of sulfidic materials in the upper 50 cm of the soil. Diagnostic/ Differentiating Criteria Histosols Saprists 1. Sulfisaprists 1. Terric Sulfisaprists: Sulfisaprists that have a mineral layer 30 cm or more thick that has its upper boundary within the control section, below the surface tier. 2. Typic Sulfisaprists: Other Sulfisaprists Entisols Aquents 1. Sulfaquents 1. Haplic: In some horizon at a depth between 20 and 50 cm below the mineral soil surface, either or both: 1) n value of 0.7 or less; or 2) less than 8 percent clay in the fine-earth fraction 2. Histic: Other Sulfaquents that have a histic epipedon 3. Thapto-Histic: Other Sulfaquents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface 4. Typic: Other Sulfaquents 2. Hydraquents 1. Sulfic: Hydraquents that have, within 100 cm of the mineral soil surface, one or both of the following: 1) sulfidic materials; or 2) a horizon 15 cm or more thick that has all of the characteristics of a sulfuric horizon, except that it has a pH value between 3.5 and 4.0 2. Thapto-Histic: Other Hydraquents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface 3. Typic: Other Hydraquents 149 At the family level of classification, classes are differentiated according to five groups of criteria: 1) particle-size class; 2) mineralogical class; 3) cation-exchange activity class; 4) reaction class; and 5) temperature class. Particle-size classes of the subaqueous soils included sandy, coarse-loamy (>15% sand and < 18% clay), coarse- silty (<15% sand and <18% clay), fine-loamy (>15% sand and > 18 to 35% clay), fine-silty (<15% sand and 18 to 35% clay), and fine (>35% clay) * . The mineralogical class was determined for four pedons representing the major soils found in Chincoteague Bay. The particle-size distributions of these pedons are presented in Table 4-7. The grain counts for the horizons constituting the mineralogy control section of these select pedons are presented in Table 4-8. The minerals identified in the sand fractions included quartz, feldspars, mica, amphibole, garnet, diatoms, sponge spicules, and opaque minerals. The weighted average of the mineral fractions for each pedon, based on the particle-size control section, is presented in Table 4-9. For loamy and sandy soils the mineralogy class was determined from the grain counts of the dominant two or three sand fractions. Semi-quantitative estimates derived from the x-ray diffraction patterns of the mineral abundances in the fine silt fraction and coarse silt fraction of the loamy soils are presented in Table 4-10. The silt fractions are dominated by quartz, but also contain albite, amphibole, mica, kaolinite, ilmenite, and orthoclase minerals (Figure 4-32, 4-33, 4-34, 4-35). The mineralogy of loamy textured soils located on the mainland cove and lagoon bottom was determined to be mixed, since no single mineral was dominant in the 2 to 0.02 mm fractions. The pedon (CB01) located on the storm-surge washover fan flat was a sandy soil and * Note that for family particle size classification, Soil Taxonomy specifies that very fine sand (50- 100?m) be included within the silt. Thus, ?sand? is really the fine and coarser sands. 150 contained 91.8% quartz and less than 10% weatherable minerals. The mineralogical composition of this pedon is borderline when taking into account the probable percentage error of ? 2.0% this pedon could be placed into the siliceous or mixed mineralogy class (the siliceous mineralogy class requires more than 90% silica minerals in the 0.02 to 2.0 mm fraction (Soil Survey Staff, 2006)). The soils in the mainland coves and the lagoon bottom contain more weatherable minerals than the sample on the storm-surge washover fan flat, however we have decided to also include these soils into the mixed mineralogy class until additional data can be collected to confirm the quantity of quartz and weatherable minerals found in sandy soils located on the storm-surge washover fan flat landscapes. Semi-quantitative estimates of the mineral abundances in the clay fraction of the loamy soils are presented in Table 4-11. The clay fractions contain quartz, illite, chlorite, vermiculite, kaolinite, amphiboles, cristobalite, and feldspar minerals (Figures 4-36, 4-37, 4-38, 4- 39, 4-40, 4-41). During the removal of the organic matter from samples CB11 Cg1 and Cg2, jarosite formed in the clay fraction. The hydrogen peroxide used to remove organic matter oxidized the sulfide bearing minerals generating sulfuric acid and lowering the pH. This created an environment conducive to the formation of jarosite. Thus, the presence of jarosite in these samples was an artifact from the pretreatment of these samples. The cation-exchange activity classes are only used to describe finer textured soils, which does not include the sandy particle-size family class. The cation- exchange activity class is defined using the ratio of cation exchange capacity (CEC) to percent clay. The CEC was not measured for the subaqueous soils in Chincoteague 151 Table 4-7. Particle-size distribution for select samples used for assessing the mineralogy of subaqueous soils. Sample %S %Si %C %fSi %cSi %vcS %cS %mS %fS %vfS CB01 Cg1, 14-76 cm 99.1 0.5 0.4 nd ? nd 0.3 7.3 34.0 56.6 0.8 CB01 Cg2, 76-103 cm 98.0 1.2 0.8 nd nd 0.0 0.7 3.1 83.9 10.2 CB11 Cg1, 12-36 cm 11.2 51.3 37.5 26.9 24.4 0.1 0.4 1.0 6.5 3.2 CB11 Cg2, 36-56 cm 6.5 56.1 37.4 34.3 21.8 0.2 0.9 0.9 2.8 1.7 CB18 Cg, 8-50 cm 18.9 47.1 34.1 19.4 27.7 0.0 0.1 0.1 8.2 10.4 CB18 Cg, 50-100 cm 23.3 47.7 29.0 22.2 25.5 0.0 0.2 0.1 8.9 14.1 CB58 Cg1, 14-37 cm 75.8 14.8 9.4 5.6 9.2 0.1 0.1 0.2 49.7 25.7 CB58 Cg2, 37-106 cm 67.8 20.4 11.8 7.6 12.8 0.0 0.2 0.2 21.3 46.0 ? not determined 152 Table 4-8. Mineralogical composition of the select samples based on the grain counts of the two or three dominant fractions that comprised 67% or more (by weight) of all fractions from 0.02 to 2.0 mm. Sample Frac. Quartz Feldspar Mica Opaque Garnet Amphibole Diatoms/Sponge Spicules Other --------------------------------------------------%--------------------------------------------------------------- CB01 Cg1, 14-76 cm mS 96.3?2.0 3.3?2.0 0.0 0.0 0.3?0.5 0.0 0.0 0.0 CB01 Cg1, 14-76 cm fS 91.3?3.2 4.7?2.6 0.0 3.0?1.9 0.3?0.5 0.0 0.0 0.7?0.8 CB01 Cg2, 76-103 cm fs 89.0?3.5 9.3?3.4 0.0 1.3?1.3 0.3?0.5 0.0 0.0 0.0 CB11 Cg1, 12-36 cm fS 76.3?4.7 21.7?4.5 0.3?0.5 1.3?1.3 0.0 0.3?0.5 0.0 0.0 CB11 Cg1, 12-36 cm CSi 51.3?5.6 38.0?5.4 2.7?1.8 3.3?2.0 0.0 4.0?2.4 0.7?0.8 0.0 CB11 Cg2, 36-56 cm fS 78.0?4.5 20.3?4.4 0.0 0.7?0.8 0.0 0.3?0.5 0.7?0.8 0.0 CB11 Cg2, 36-56 cm CSi 45.3?5.6 40.7?5.5 2.3?1.7 2.7?1.8 0.0 7.3?3.0 1.7?1.5 0.0 CB18 Cg, 8-50 cm vfS 74.3?4.8 15.7?4.0 2.3?1.7 1.0?1.0 0.0 6.0?2.7 0.7?0.8 0.0 CB18 Cg, 8-50 cm CSi 64.7?5.4 21.3?4.5 3.3?2.0 1.7?1.5 0.0 9.0?3.4 0.0 0.0 CB18 Cg, 50-100 cm vfS 54.0?5.6 30.0?5.3 4.3?2.5 1.3?1.3 0.0 10.0?3.4 0.3?0.5 0.0 CB18 Cg, 50-100 cm CSi 43.0?5.5 38.0?5.4 4.7?2.6 2.3?1.7 0.0 12.0?3.5 0.0 0.0 CB58 Cg1, 14-37 cm fS 69.7?5.1 25.0?4.9 2.0?1.6 1.3?1.3 0.0 2.0?1.6 0.0 0.0 CB58 Cg1, 14-37 cm vfS 58.3?5.6 29.7?5.1 1.3?1.3 1.7?1.5 0.0 9.0?3.3 0.0 0.0 CB58 Cg2, 37-106 cm fS 60.7?5.6 27.0?5.0 7.7?2.8 0.0 0.0 3.7?2.4 1.0?1.0 0.0 CB58 Cg2, 37-106 cm vfS 56.3?5.7 31.7?5.2 2.0?1.6 0.7?0.8 0.0 9.3?3.4 0.0 0.0 153 Table 4-9. Mineralogical composition of the select samples based on the grain counts of the dominant two or three dominant fractions that comprised 67% or more (by weight) of all fractions from 0.02 to 2.0 mm. The values represent the weighted average of the mineral fractions based on the horizon thickness in the control section. The pedons are not dominated by a single mineral and were classified as having a mixed mineralogy. Quartz Feldspar Mica Opaque Garnet Amphibole Diatoms/Sponge Spicules Other Sample Control Section ------------------------------------------------------%----------------------------------------------------------- CB01 25-100 cm 91.8 5.8 0.0 1.7 0.3 0.0 0.0 0.3 CB11 25-56 cm 66.5 27.7 0.9 1.6 0.0 2.4 0.8 0.0 CB18 25-100 cm 54.5 29.5 4.0 1.7 0.0 10.0 0.2 0.0 CB58 25-100 cm 59.0 29.6 3.5 0.6 0.0 7.0 0.3 0.0 154 Table 4-10. Semi-quantitative mineral estimates of the fine silt (0.002 to 0.02 mm) and coarse silt (0.02 to 0.05 mm) fractions of selected samples. The composition of these fractions indicates that no single mineral fraction was dominant. Sample Quartz Albite Mica Amphiboles Orthoclase Kaolinite Ilmenite CB11 Cg1, 12-36 cm fSi XXX ? XX X X X X x CB11 Cg2, 37-56 cm fSi XXX XX X X X X x CB18 Cg, 8-50 cm fSi XXX XX X X x CB18 Cg, 50-100 cm fSi XXX XX X X x CB58 Cg1, 14-37 cm fSi XXX XX X X x x CB58 Cg1, 14-37 cm cSi XXX XX X X x x x CB58 Cg2, 37-106 cm fSi XXX XX X X x x CB58 Cg2, 37-106 cm cSi XXX XX X X x x x ? x: 0-5%; X: 5-10%; XX: 10-30%; XXX: 30-70%; and XXXX: >70%. 155 Figure 4-32. X-ray diffraction pattern of the fine silt fraction from sample CB11 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), and ilmenite (Il). 156 Figure 4-33. X-ray diffraction pattern of the fine silt fraction from sample CB18 Cg 8-50 cm and Cg 50-100 cm. The sample is dominated by quartz (Q) and also contains albite (Al), mica (M), kaolinite (K), and ilmenite (Il). 157 Figure 4-34. X-ray diffraction pattern of the fine silt fraction from sample CB58 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), and ilmenite (Il). 158 Figure 4-35. X-ray diffraction pattern of the coarse silt fraction from sample CB58 Cg1 and Cg2. The sample is dominated by quartz (Q) and also contains amphibole (A), albite (Al), mica (M), kaolinite (K), orthoclase (O), and ilmenite (Il). 159 Table 4-11. Semi-quantitative mineral estimates of the clay fraction of selected samples. The composition of these fractions indicates that no single mineral fraction was dominant. The jarosite peaks are an artifact in the clay fraction created during the removal of the organic matter from sample CB11 Cg1 and Cg2. Sample Quartz Illite Chlorite Vermiculite Kaolinite Feldspars Amphiboles Cristobalite Jarosite CB11 Cg1, 12-36 cm XX ? XXX XX X XX X x x x CB11 Cg2, 36-56 cm XX XXX XX X XX X x x x CB18 Cg, 8-50 cm XX XXX XX X XX X x x CB18 Cg, 50-100 cm XX XXX XX X XX X x x CB58 Cg1, 14-37 cm XX XXX XX X XX X x x CB58 Cg2, 37-106 cm XX XXX XX X XX X x x ? x: 0-5%; X: 5-10%; XX: 10-30%; XXX: 30-70%; and XXXX: >70%. 160 Figure 4-36. X-ray diffraction pattern of the clay fraction from sample CB11 Cg1. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), cristobalite (Cb), and jarosite (J) minerals. 161 Figure 4-37. X-ray diffraction pattern of the clay fraction from sample CB11 Cg2. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), gibbsite (G), quartz (Q), feldspar (F), cristobalite (Cb), and jarosite (J) minerals. 162 Figure 4-38. X-ray diffraction pattern of the clay fraction from sample CB18 Cg 8-50 cm. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), orthoclase (O), and cristobalite (Cb) minerals. 163 Figure 4-39. X-ray diffraction pattern of the clay fraction from sample CB18 Cg 50-100 cm. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals. 164 Figure 4-40. X-ray diffraction pattern of the clay fraction from sample CB58 Cg1. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals. 165 Figure 4-41. X-ray diffraction pattern of the clay fraction from sample CB58 Cg2. The sample contained vermiculite (V), chlorite (C), illite (I), amphibole (A), kaolinite (K), quartz (Q), feldspar (F), and cristobalite (Cb) minerals. 166 Bay. Therefore, our cation-exchange activity class for each of the subaqueous soils was assumed to be similar to the cation-exchange activity class of the subaerial soils located on the surrounding Delmarva Peninsula from which the subaqueous soils were derived. Because the cation-exchange activity class of the subaerial soils on the Delmarva Peninsula was generally active it was assumed that the cation-exchange activity class for the subaqueous soils was also active (0.4 to 0.6) (Soil Survey Staff, 2006). The reaction class for the Sulfaquents was determined to be nonacid based on the pH of freshly thawed samples, which ranged from 6.5 to 7.5. The reaction class for Histosols was determined to be Euic. The temperature class for the subaqueous soils of Chincoteague Bay is mesic (mean annual soil temperature ranged from 8 to 15?C). Table 4-12 shows how the soils examined in Chincoteague Bay were classified to the family level using the existing structure in Soil Taxonomy. Nearly all of the soils were classified into the Sulfaquent great group, and most were classified into either the Haplic Sulfaquent or the Typic Sulfaquent subgroup classes. Classification Using Proposed Changes to Soil Taxonomy A modification to Soil Taxonomy to better accommodate subaqueous soils has been proposed by Northeast Regional Cooperative Soil Survey Subaqueous Soils Committee (2007). This new proposal adds Wassents and Wassists as new suborders. The new suborders are defined as having a positive water potential at the soil surface for 90% of each day (i.e. subaqueous). That portion of the classification hierarchy used for describing subaqueous soils using the proposed classification (Soil Taxonomy) is shown in Table 4-13. In the next level of the Soil Taxonomy, three great groups were proposed for Wassents, being (in descending hierarchal order) Psammowassents, 167 Sulfiwassents, and Hydrowassents. The order in which the great groups key out is based on the perceived significance of soil properties. In the Wassents the great groups are ordered differently than is currently done in the Aquents great groups. In the Wassents, the presence of dominantly sandy soil texture was deemed of greater importance than the presence or absence of sulfidic materials in the upper 50 cm of the soil surface (which is very common in estuarine subaqueous soils) and thus Psammowassents key out before Sulfiwassents. Psammowassents are Wassents with textures of loamy fine sand or coarser. Sulfiwassents are Wassents that have sulfidic materials within 50 cm of the soil surface. Most of the Wassents were classified as Sulfiwassents. One soil profile was classified into the Hydrowassents, which had neither sulfidic material within 50 cm of the soil surface nor was dominantly sandy in texture. Table 4-14 shows the classification of the 146 subaqueous soil profiles to the family level, using the proposed soil taxonomic system. The distribution of the subaqueous soils and their classification to the family level is shown in Figure 4-42. All of the 144 soil profiles that were classified as Entisols met the criteria for the proposed Wassents subgroup. These 144 soils fell within the six proposed subgroups of Sulfic Psammowassents, Haplic Sulfiwassents, Thapto-Histic Sulfiwassents, Aeric Sulfiwassents, Fluvic Sulfiwassents, and Sulfic Hydrowassents. These subgroups have essentially the same diagnostic criteria as used for subgroups of Sulfaquents (see Table 4-12). The components of the family classification under the new proposed scheme would be essentially unchanged from the current classification system. 168 Table 4-12. Classification of 146 subaqueous soils described in Chincoteague Bay to the family level using current Soil Taxonomy. Numbers in parenthesis indicate the number of pedons in each taxon. Order Suborder Great Group Subgroup Family (PS) Class Histosols (2) Saprists (2) Sulfisaprists (2) Terric Sulfisaprists (2) Fine-silty, Terric Sulfisapists (2) Entisols (144) Aquents (144) 1. Sulfaquents (143) 1. Haplic Sulfaquents (49) 1. Sandy, Haplic Sulfaquents (30) 2. Sandy over loamy, Haplic Sulfaquents (1) 3. Coarse-loamy, Haplic Sulfaquents (11) 4. Fine-loamy, Haplic Sulfaquents (1) 5. Fine-silty, Haplic Sulfaquents (5) 6. Fine, Haplic Sulfaquents (1) 2. Thapto-Histic Sulfaquents (7) 1. Coarse-loamy, Thapto- Histic Sulfaquents (1) 2. Coarse-silty, Thapto- Histic Sulfaquents (1) 3. Fine-loamy, Thapto- Histic Sulfaquents (1) 4. Fine-silty, Thapto-Histic Sulfaquents (3) 5. Fine, Thapto-Histic Sulfaquents (1) 3. Typic Sulfaquents (87) 1. Coarse-loamy, Typic Sulfaquents (7) 2. Fine-loamy, Typic Sulfaquents (10) 3. Fine-silty, Typic Sulfaquents (69) 4. Fine, Typic Sulfaquents (1) 2. Hydraquents (1) 1. Sulfic Hydraquents (1) 1. Coarse-silty, Sulfic Hydraquents (1) 169 Table 4-13. That portion of the proposed changes to Soil Taxonomy (2006) used in the classification of 146 subaqueous soils in Chincoteague Bay. Diagnostic/ Differentiating Criteria Histosols Wassists 1. Sulfiwassists: presence of sulfidic materials in the upper 50 cm of the soil. 1. Sapric: Sulfiwassists that have more thickness of sapric soil materials than any other kind of organic soil materials. Entisols Wassents 1. Psammowassents: textures of loamy fine sand or coarser. 1. Sulfic: Psammowassents that have sulfidic materials within 100 cm of the mineral soil surface. 2. Sulfiwassents: presence of sulfidic materials in the upper 50 cm of the soil. 1. Haplic: Sulfiwassents that have, in some horizons at a depth between 20 and 50 cm below the mineral soil surface, either or both: 1. An n value of 0.7 or less; or 2. Less than 8 percent clay in the fine- earth fraction. 2. Thapto-Histic: Sulfiwassents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface. 3. Fluvic: Sulfiwassents that have either 0.2 percent or more organic carbon of Holocene age at a depth of 125 cm below the mineral soil surface or an irregular decrease in content of organic carbon from a depth of 25 cm to a depth of 125 cm or to a densic, lithic, or paralithic contact if shallower. 4. Aeric: Sulfiwassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. 5. Typic: Other Sulfiwassents. 170 Table 4-13. Continued. Diagnostic/ Differentiating Criteria Entisols Wassents 3. Hydrowassents: at a depth between 20 and 50 cm below the mineral soil surface, both an n value of more than 0.7 and 8 percent or more clay 1. Sulfic: Hydrowassents that have a sulfidic materials within 100 cm of the mineral soil surface. 171 Table 4-14. Classification of 146 subaqueous soils described in Chincoteague Bay using the proposed classification. Numbers in parenthesis indicate the number of pedons in the taxon. Order Suborder Great Group Subgroup ? Family (PS) Class Histosols (2) Wassists (2) Sulfiwassists (2) Sapric Sulfiwassists (2) Entisols (144) Wassents (144) 1. Psammowassents (20) 1. Sulfic Psammowassents (20) 2. Sulfiwassents (124) 1. Haplic Sulfiwassents (26) 1. Sandy, Haplic Sulfiwassents (10) 2. Sandy over loamy, Haplic Sulfiwassents (1) 3. Coarse-loamy, Haplic Sulfiwassents (13) 4. Fine-loamy, Haplic Sulfiwassents (2) 5. Fine, Haplic Sulfiwassents (1) 2. Thapto-histic Sulfiwassents (6) 1. Coarse-silty, Thapto- histic Sulfiwassents (1) 2. Fine-loamy, Thapto- histic Sulfiwassents (2) 3. Fine-silty, Thapto- histic Sulfiwassents (2) 4. Fine, Thapto-histic Sulfiwassents (1) 3. Aeric Sulfiwassents (2) 1. Coarse-loamy, Aeric Sulfiwassents (2) 4. Fluvic Sulfiwassents (88) 1. Coarse-loamy, Fluvic Sulfiwassents (4) 2. Fine-loamy, Fluvic Sulfiwassents (9) 3. Fine-silty, Fluvic Sulfiwassents (74) 4. Fine, Fluvic Sulfiwassents (1) 3. Hydrowassents (1) 1. Sulfic Hydrowassents (1) 1. Coarse-silty, Sulfic Hydrowassents (1) ? see Table 4-13 for explanation. 172 Figure 4-42. Classification of subaqueous soil profiles in Maryland?s portion of Chincoteague Bay using the proposed changes to Soil Taxonomy. 173 Development of Subaqueous Soil Series The soil series is the 6 th and lowest category in Soil Taxonomy and further defines differences within a family that impact the use of the soils. Series differentiating criteria can include soil properties used as criteria at higher levels of Soil Taxonomy, other soil characteristics such as soil color or texture, or the depth at which unique horizons or characteristics are found within the soil profile. Therefore, the series control section can include properties from the soil surface to a depth of up to 2 m. There were several subaqueous soil series already established as a result of the work done by Demas (1998) in Sinepuxent Bay, MD. These series included Demas ? (sandy, Haplic Sulfaquents), Sinepuxent (coarse-loamy, Typic Sulfaquents), Southpoint (fine-silty, Thapto-histic Sulfaquents), and Tizzard (sandy over loamy, aniso, Sulfic Fluvaquents). Although these soil series accommodate several of the soils found throughout Chincoteague Bay, they do not accommodate most of the subaqueous soils described in this study. Therefore eight new series are proposed here to accommodate the remaining soils. Table 4-15 shows the names and family level classification for the eight additional subaqueous soil series proposed for use in Chincoteague Bay, Maryland. The main criteria differentiating these series, as well as some accessory criteria and characteristics, are shown in Table 4-16. The classification to the series level of the pedons described in Chincoteague Bay is shown in Figure 4-43. The term taxadjunct is used for soils that have properties outside of the range of any recognized series because of one or more differentiating characteristics. A taxadjunct is given the name of an established series that is most similar in characteristics and in this sense is adjunct to the series. And while it is not part of the ? Named posthumously after the untimely death of George P. Demas in 1999. George Demas was considered as a pioneer in subaqueous soils research. This soil series was given the name Wallops in Demas? 1998 dissertation ?Subaqueous Soils of Sinepuxent Bay?. 174 series, it is treated as though it were a part of the named series (Soil Survey Division Staff, 1993). For example, the Southpoint soil series is a fine-silty, Thapto-histic Sulfiwassents, which recognizes the presence of buried organic horizons within the upper 100 cm of the soil. Core CB26 was classified as a fine, Haplic Sulfiwassents, which currently does not have a named series. Because this pedon does have a buried organic horizon within the upper 100 cm of the soil surface, and is thus similar to the Southpoint soils, it was classified as a Southpoint Taxadjunct (Tax.). It differs from Southpoint series primarily by having low n value materials within the upper 50 cm of the soil surface. Four of the proposed new series are classified in the same fine-silty, Fluvic Sulfiwassents family, but they possess a number of properties that differ significantly within the series control section. The proposed Truitt Series exhibits a buried organic horizon that has its upper boundary between 1 to 2 m. A description of the modal pedon for the Truitt Series, (CB97) is shown in Table 4-17. Truitt differs from the Southpoint series because the organic horizons start below 1 m and are thinner, whereas, in the Southpoint Series the organic horizons start within the upper 1 m of the soil surface and the thickness of the organic horizon is at least 20 cm. The Tingles series differs from Truitt due to the absence of the organic horizons in Tingles and the n values must be > 1 throughout the entire soil profile. A description of the modal pedon for the Tingles Series (CB18) is shown in Table 4-18. The proposed Coards series differs from Truitt by lacking a buried organic horizon and differs from Tingles by having higher clay percentages (> 30%) and by having n values > or >> 1 (much greater than 1) throughout the entire soil profile. These soils have a very low bearing capacity and were often 175 Table 4-15. New soil series proposed for use in Chincoteague Bay, Maryland. Soil Series Name Soil Classification Truitt Fine-silty, mixed, active, nonacid, mesic Typic Sulfiwassents Tingles Fine-silty, mixed, active, nonacid, mesic Typic Sulfiwassents Cottman Coarse-loamy, mixed, active, nonacid, mesic Haplic Sulfiwassents Figgs Fine-loamy, mixed, active, nonacid, mesic Typic Sulfiwassents Tumagan Sapric Sulfiwassists Middlemoor Fine-silty, mixed, active, nonacid, mesic Typic Sulfiwassents Coards Fine-silty, mixed, active, nonacid, mesic Typic Sulfiwassents Thorofare Sandy, mixed, nonacid, mesic Haplic Sulfiwassents 176 Table 4-16. Differentiating criteria for proposed and established soil series for Chincoteague Bay, MD. Those soil series that are already officially established are shown as shaded. Subaqueous Soil Series Name and Classification Series Criteria Differentia Accessory Criteria Coards Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) N values >1 throughout the soil profile 1. Sulfidic materials within upper 50 cm of the soil surface 2. SiL, SiCL, or SiC textures Tingles Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 1. N values >0.7 throughout the soil profile 2. >0.2% OC or irregular distribution of OC from 25-100 cm 1. Sulfidic materials within the upper 50 cm of the soil surface 2. High organic carbon contents 3. SiL, L, CL, SiCL textures in control section Middlemoor Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 1. N values >0.7 in upper 100 cm; N values < 0.7 deeper than 100 cm 2. >0.2% OC or irregular distribution of OC from 25-100 cm 1. Sulfidic materials within upper 50 cm of the soil surface 2. SiCL, L, CL, or SiL textures in the control section 3. Discontinuity with coarser textures deeper in soil profile Truitt Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 1. Buried organic horizons deeper than 100 cm (upper boundary begins within 200 cm), at least 5 cm thick 2. >0.2% OC or irregular distribution of OC from 25-100 cm 1. Sulfidic materials within upper 50 cm of the soil surface 2. High organic carbon contents 3. N values > 0.7 in upper 150 cm of the soil surface 4. Buried pre-Holocene subaerial soils below organic horizons Southpoint Fine-silty, Thapto- Histic Sulfaquents (Fine-silty, Thapto- Histic Sulfiwassents) Buried organic horizons at least 20 cm thick that starts within the upper 100 cm of the soil surface 1. Sulfidic materials within the upper 50 cm of the soil surface Tumagan Fine-silty, Terric Sulfisaprists (Sapric Sulfiwassists) Buried organic horizons at least 40 cm thick that starts within the upper 80 cm of the soil surface 1. Subaqueous, permanently submerged 2. Less than 30 cm of recent estuarine sediments burying the organic soil 177 Table 4-16 Continued. Subaqueous Soil Series Name and Classification Series Criteria Differentia Accessory Criteria Figgs (Fine-loamy, Typic Sulfaquents) Fine-loamy, Fluvic Sulfiwassents 1. N values > 0.7 within upper 100 cm of the soil surface 2. >0.2% OC or irregular distribution of OC from 25-100 cm 1. Sulfidic materials within the upper 50 cm of the soil surface 2. SiL, CL, L, fSL textures in the control section Sinepuxent Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents) 1. N values <0.7 in the control section 2. >0.2% OC or irregular distribution of OC from 25-100 cm 1. SL, SiL, S, LS textures in the control section 2. At least one lithologic discontinuity Cottman Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) N values < 0.7 or less than 8 percent clay within 20 to 50 cm of the soil surface 1. Sulfidic materials within the upper 50 cm of the soil surface 2. SL, L, LS, SiCL textures within the control section 3. Discontinuity with finer textured materials Tizzard Sandy over loamy, aniso, Sulfic Fluvaquents (Sandy over loamy, aniso, Haplic Sulfiwassents) Lithologic discontinuity within the control section with sandy sediments overlying silty sediments 1. Sulfidic materials within the upper 100 cm (50cm) of the soil surface Thorofare Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) fSL or coarser textures throughout the soil profile 1. N values < 1 in the control section 2. No discontinuity with finer textured materials Whittington Typic Psammaquents (Fluventic Psammowassents) Buried A horizons within the soil profile-irregular distribution of OC content at 125 cm below the soil surface 1. LfS or coarser textures in the control section 2. No sulfidic materials within the upper 100 cm of the soil surface Trappe Typic Psammaquents (Aeric Psammowassents) Chroma 3 or more, abundance 40% or greater within the control section 1. LfS or coarser textures throughout control section 2. no sulfidic materials within upper 100 cm of the soil surface 178 Table 4-16 Continued. Subaqueous Soil Series Name and Classification Series Criteria Differentia Accessory Criteria Demas Typic Psammaquents (Sulfic Psammowassents) N values < 0.7 throughout the profile 1. LfS or coarser textures throughout profile 2. Sulfidic materials within upper 100 cm of the soil surface May have a lithologic discontinuity with coarser textured sand Unnamed B Coarse-silty, Sulfic Hydraquents (Coarse-silty, Sulfic Hydrowassents) Contains sulfidic materials within 50 to 100 cm of the soil surface 1. n values > 1 in control section 2. L textures in the control section Unnamed C Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Aeric Sulfiwasents) Contains sulfidic materials within 50 cm of the soil surface and chroma 3 or more, abundance 40% or greater within the control section 1. fSL or coarser textures in control section 2. n values <1 in control section 179 Figure 4-43. Classification of pedons described in Chincoteague Bay, MD, to the series level. 180 described in the field as having a ?soup-like? or ?jelly? consistency in some horizons. A description of the modal pedon for the Coards series (CB93) is shown in Table 4-19. The Middlemoor Series differs from Truitt by lacking a buried organic horizon, from Tingles by having n values < 1, and from Coards by having less than 30% clay and n values < 1. A description of the modal pedon for the Middlemoor series (CB39) is shown in Table 4- 20. The remaining four proposed subaqueous soil series differ at higher categories of Soil Taxonomy (mainly at the family or subgroup level). The Cottman series has either an n value < 0.7 or < 8% clay from 20 to 50 cm of the soil surface (making it Haplic) and a discontinuity within the soil profile with finer textured materials below 100 cm. A description of the modal pedon for the Cottman series (CB55) is shown in Table 4-21. The proposed Thorofare series differs from Cottman with sandy textures (fine sandy loam, sandy loam, loamy sand, loamy fine sand, or sand) and n values < 0.7 occurring throughout the soil profile (is also Haplic). A description of the modal pedon for the Thorofare series (CB29) is shown in Table 4-22. The Figgs series has n values >0.7 in the upper 1m of the soil profile and silt loam, clay loam, loam, or sandy loam textures in the particle-size control section (making it Fluvic). A description of the modal pedon for the Figgs series (CB41) is shown in Table 4-23. The final proposed series, Tumagan, included soils that are permanently submerged Histosols that have less than 30 cm of recent estuarine material deposited on top of the organic horizon. These soils were recently submerged marshes and occur adjacent to the mainland shoreline. A description of the modal pedon for the Tumagan series (CB146) is shown in Table 4-24. 181 Table 4-17. Field morphological description of subaqueous soil profile CB97. Modal pedon for the Truitt Series. 38? 08? 35.9? N, 75? 16? 30.0? Water Depth 220 cm Sample CB97 Fine-silty, Fluvic Sulfiwassents Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Abun .% Color Gr. Shape Wet Const. n value Shells % Intensity of H 2 S A 2 a SiC 5Y 3/1 0 ma ns >1 Strong Cg1 76 c SiC SiL 10Y 3/1 0 ma ms >1 Strong Cg2 95 c C L 10Y 3/1 0 ma ms >1 Strong Cg3 131 c SiC SiCL 10Y 3/1 0 ma ms >1 3 Strong Cg4 145 c SiC SiCL 10Y 3/1 2 2.5Y 5/6 0 ma ms >1 Strong Cg5 168 c SiC SiC 5Y 3/2 10Y 3.5/1 15 2.5Y 5/6 0 ma ss >1 2 Strong Oa/Cg 195 a MkSiCL - 5Y 4/1 15 2.5Y 5/6 0 ma ss >1 Strong Oab1 213 c Mk - 5Y 3/2 40 2.5Y 5/4 Strong Oab2 224 c Mk - 10YR 2/1 Strong 2Ab 245 c MkL L 10YR 2/1 0 ma ss >1 Strong 2Cgb1 260 c SL L 5GY 4/1 0 ma ms >1 None 2Cgb2 266 - SL SL 5GY 5/1 3-5% 5Y 5/4 0 ma ss >1 None Remarks: Profile description by D. Balduff, 21 August 2005 at 8:12 am Sampled using McCauley peat auger 0% vegetative cover, worm tubes on surface 182 Table 4-18. Field morphological description of subaqueous soil profile CB18. Modal pedon for the Tingles Series. 38? 08? 19.95? N, 75? 14? 43.10? W Water Depth 270 cm Sample CB18 Fine-silty, Fluvic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 8 a SiCL/SiC 10Y 2.5/0.5 0 ma vs >>>1 None Cg 50 SiCL/SiC SiCL 10Y 3/1 0 ma vs >>1 100 CL 150 SiCL 200 SiCL 245 CL Remarks: Profile described by D. Balduff, M.Stolt, and M. Rabenhorst, 21 September 2004 at 3:00pm Sampled using McCauley peat auger 0% vegetative cover 183 Table 4-19. Field morphological description of subaqueous soil profile CB95. Modal pedon for the Coards Series. 38? 02? 52.30? N, 75? 19? 26.90? W Water Depth 190 cm Sample CB93 Fine-silty, Fluvic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 A SiC SiL 5Y 4/1 0 ma ns >>1 None A2 15 C SiC SiL 10Y 2.5/1 0 ma vs >1 2 Weak Cg1 42 C SiC SiL 10Y 3/1 0 ma ms >1 Strong Cg2 81 G SiC SiCL 10Y 3/1 3 5Y 4/4 0 ma ms >1 2 Strong Cg3 210 SiC SiCL 10Y 3.5/1 0 ma vs >1 Strong Remarks: Profile described by D. Balduff, 20 July 2005 at 10:00 am Sampled using McCauley peat sampler 0% vegetative cover 184 Table 4-20. Field morphological description of subaqueous soil profile CB39. Modal pedon for the Middlemoor Series. 38? 05? 56.50? N, 75? 19? 59.20? W Water Depth 130 cm Sample CB39 Fine-silty, Fluvic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 1 SiC 5Y 4/2 0 ma ms >1 Weak A2 12 SiC SiCL 10Y 2.5/1 0 ma ms >1 1 None Cg1 43 SiC SiCL 10Y 3/1 0 ma ms >1 None Cg2 57 SiC SiC 5GY 3/1 0 ma ms >>1 None Cg3 126 SiC SiL 10Y 3/1 0 ma ms >1 None 2Cg4 161 LS fSL 10Y 3/1 0 sg ss <0.7 None 2Cg5 198 LS LfS 5Y 5/2 0 sg ss <0.7 None Remarks: Profile described by D. Balduff, 23 June 2005 at 12:22 pm Sampled using McCauley peat auger 0% vegetative cover, worm tubes on surface 185 Table 4-21. Field morphological description of subaqueous soil profile CB55. Modal pedon for the Cottman Series. 38? 04? 50.40? N, 75? 15? 52.40? W Water Depth 185 cm Sample CB55 Coarse-loamy, Haplic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL fS 5Y 4/1 0 ma ns <0.7 Strong A2 12 a SL fS N 3 0 ma ns <0.7 5 Strong Cg1 41 c SL LfS 10Y 3.5/1 0 ma ss <0.7 3 Strong Cg2 90 g SL LfS 5GY 3.5/1 3 2.5Y 3/3 0 ma ss 0.7-1 1 Strong 2Cg3 143 g C L 5GY 3/1 0 ma ms >1 1 Strong 2Cg4 162 c L SL 10Y 3/1 4 5Y 4/4 0 ma ss 0.7-1 1 Strong 2Cg5 198 - SiC L 10Y 3/1 7 5Y 4/4 0 ma ms >1 1 Strong Remarks: Profile described by D. Balduff, 6 July 2005 at 8:15 am Sampled using Vibracorer, depth inside core 170 cm, depth outside core 165 cm 0% vegetative cover, worm tubes on surface 186 Table 4-22. Field morphological description of subaqueous soil profile CB56. Modal pedon for the Thorofare Series. 38? 09? 28.2? N, 75? 13? 0.10? W Water Depth 190 cm Sample CB29 Sandy, Haplic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a fSL 5Y 3/1 0 ma VS/VP >1 <1 0 Strong Cg1 6 c fSL 5Y 2.5/1 0 ma VS/VP >1 1 Strong Cg2 24 c fSL N 3/ 0 ma MS/MP <0.7 Trace Strong Cg3 89 c SL LfS 10Y 3/1 0 ma SS/NP <0.7 Trace Strong 2Ab 111 c LS fS 5GY 3/1 0 sg NS/NP <0.7 35 Strong 2Cgb 159 - LS N 4/ 0 sg NS/NP <0.7 2 Strong Remarks: Profile described by D. Balduff, 8 June 2005 at 9:45 am Sampled using Vibracorer, depth inside core 235 cm, depth outside core 230 cm 187 Table 4-23. Field morphological description of subaqueous soil profile CB41. Modal pedon for the Figgs Series. 38? 06? 07.20? N, 75? 19? 00.40? W Water Depth 130 cm Sample CB41 Fine-loamy, Fluvic Sulfiwassents Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a L - 5Y 3.5/1 0 ma Strong A2 17 c L FSL 10Y 2.5/1 0 ma 0.7-1 1 Strong 2Cg1 52 c FSL CL 10Y3/1 0 ma >1 15 Strong 2Cg2 143 - SiC CL 5GY 3.5/1 0 ma >1 None Remarks: Profile described by D. Balduff, 24 June 2005 at 10:49 am Sampled using McCauley peat sampler 0% vegetative cover, worm tubes on surface 188 Table 4-24. Field morphological description of subaqueous soil profile CB146. Modal pedon for the Tumagan Series. 38? 12? 25.10? N, 75? 15? 2.50? W Water Depth 40 cm Sample CB146 Fine-silty, Terric Sulfisaprists Sapric Sulfiwassists Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SL 5Y 4/1 0 ma ss <0.7 Strong Cg 6 c SiC 10Y 3.5/1 10 2.5Y 5/6 0 ma ss >1 Strong Oa 24 c Mk 5Y 3/2 Strong C?g 39 c MkSiCL 10Y 3.5/1 0 ma ss >1 Strong Oab1 71 c Mk 5Y 3/2 Strong Oab2 103 c Mk 10YR 2/1 Strong C?g 160 c SiC 5GY 3.5/1 25 5Y 6/6 0 ma ss >1 Strong Oab 210 c Mk 10YR 2/2 Strong 2Ab 220 c L 10YR 2/1 7 2.5Y 4/4 0 ma ss 0.7-1 Strong 2Cgb 229 - SL 10Y 3/1 3 2.5Y 4/4 0 ma ss <0.7 Strong Remarks: Profile described by D. Balduff 18 August 2005 at 10:57 am Sampled using McCauley peat sampler 0% vegetative cover, worm tubes on surface 189 Conclusions Soils were characterized for a variety of physical and chemical properties. The particle-size analyses collected for 188 samples indicated that the field textures collected could be used for the samples that do not have particle-size data by taking into account minor systematic shifts. The presence of sulfidic materials and the concentration of sulfides in the soils is an important criterion in the classification of these soils. Based on moist incubation pH data collected for 27 pedons, most of the soils contained sulfidic materials within the profile. The lowest concentrations of acid volatile sulfides and chromium reducible sulfides were associated with the very sandy soils located on the storm-surge washover fan flats, whereas the highest concentrations were associated with the finer textured, organic rich soils in the mainland coves. Overall, the acid volatile sulfide concentrations were very low even in profiles where chromium reducible sulfides were substantial. Sandy textured soils mostly had field estimated n values less than 0.7 and the finer textured soils generally had field estimated n values greater than 1. The field estimated n values differed dramatically from the calculated n values. The field estimated n values were a better predictor of the fluidity and bearing capacity of the soils than the calculated values. The porewater salinities of surface horizons were similar to the overlying water, which ranged from 26 to 36 ppt. Salinity within pedons located on the eastern side of the bay toward the barrier island remained high with depth with values centered around 26 to 34 ppt. However, pedons located near the mainland tended to show a systematic decrease in salinity with depth. The lower salinity values associated with 190 these areas are likely the result of groundwater discharge into the bay from the surrounding watershed. The soil mineralogy of these soils were not dominated by any single mineral and were classified into the mixed mineralogy class. The sandy soils located on the storm-surge washover fan flat and paleo-flood tidal delta landforms had the lowest organic carbon contents. The amount of organic carbon stored in the upper 1m was lowest (0.7 to 3.6 kg m -2 ) in the sandy soils located on the storm-surge washover fan flat, storm-surge washover fan slope, and paleo- flood tidal delta landforms. The profiles that contained the buried organic horizons had the highest organic carbon contents within Chincoteague Bay. The lagoon bottom, fluviomarine bottom, and barrier cove landforms have moderate quantities (4.0 to 21.0 kg m -2 ) of organic carbon stored in the upper 1 m of the soils, while those soils in the mainland coves and submerged wave-cut headlands have the highest (5.0 to 34.0 kg m -2 ) organic carbon contents in the upper 1m. The carbon stored in these sediments may be produced in situ by benthic and aquatic organisms and these data may need to be considered in the global carbon storage estimates. The calcium carbonate contents are generally low in the soils throughout Chincoteague Bay. The subaqueous soils of Chincoteague Bay were better accommodated when using the proposed suborder of Wassents for classification compared to the current suborder of Aquents, which is also used for subaerial soils that are not permanently saturated. The order in which the great groups of Wassents are introduced places importance on soil texture in the control section, whereas in the Aquents the priority was placed on the presence of sulfidic materials. When the current classification scheme was used, nearly all (98%) of the subaqueous soils were classified as 191 Sulfaquents. The proposed classification recognizes the sandy soils first as Psammowassents (14%) and the remainder of the soils classify as Sulfiwassents (86%). The proposed amendment to Soil Taxonomy does a better job of differentiating soils in estuarine systems The currently approved subaqueous soil series accommodated only 24% of the soils described in Chincoteague Bay. Therefore eight additional subaqueous soil series were proposed to accommodate the remainder of the soils at the series level of classification. The proposed series were differentiated based on such properties as the presence or absence of organic horizons, soil texture in the particle-size control section, textural changes with depth, and n values throughout the profiles. By identifying and using these new soil series, the differences among the soils can be better highlighted. The properties of the soil series can then be used to assess the potential uses of these soils by ecological managers, scientists, and engineers. 192 Chapter 5: Subaqueous Soil-Landscape Relationships in Chincoteague Bay, MD Introduction Demas and Rabenhorst (2001) first identified the pedogenic processes that form subaqueous soils and demonstrated that the subaqueous soils of Sinepuxent Bay, MD were systematically distributed across landscape units. Demas (1998) developed the initial subaqueous soil-landscape models for shallow coastal bays. Later studies by Bradley and Stolt (2003) in Ninigret Pond, RI, Osher and Flannagan (2007) in Taunton Bay, ME, and Coppock et al. (2004) in Rehoboth Bay, DE, continued to define and enhance the subaqueous soil-landscape models for coastal lagoons and estuaries. Demas (1998) identified seven distinct subaqueous landforms, to which he applied the following names: mid-bay shoal, overwash fans, barrier island flats, shallow mainland coves, deep mainland coves, transition zones, and central basin. He also proposed six soil series that were found in association with the seven major landforms described in Sinepuxent Bay, MD. The dominant soils associated with each landform are presented in Table 5-1. Most of the soil series were differentiated on the basis of texture and the presence or absence of sulfidic materials in the soil profile. According to Demas, most of the sandy soils did not contain sulfidic materials. He observed, for example, that soils located on the overwash fan, shallow 193 Table 5-1. Major landforms and the associated soils found in Sinepuxent Bay, Maryland (summarized from Demas, 1998). Landform Name Series Family Level Classification (Soil Taxonomy) Distinctive Soil Properties Mid-Bay Shoal Sinepuxent Coarse-loamy, Typic Sulfaquents 1. Sulfidic materials 2. Fluid (n value >0.7) 3. Lithologic discontinuities Overwash Fans Fenwick (Whittington) Typic Psammaquents 1. Sandy 2. Non-fluid (n value <0.7) Barrier Island Flats Tizzard Coarse-loamy, Sulfic Fluvaquents 1. Sulfidic materials 2. Irregular distribution of organic C Shallow Mainland Coves Newport (Trappe) Typic Psammaquents 1. Sandy 2. Non-fluid (n value <0.7) 3. Subsoil colors, chroma 3 or greater Deep Mainland Coves South Point (Southpoint) Fine-silty, Thapto- Histic Sulfaquents 1. Buried organic horizons within 100cm of soil surface 2. Finer textured 3. Fluid (n value >0.7) 4. Sulfidic materials 5. Highest organic C contents Transition Zones Wallops (Demas) Typic Psammaquents 1. Sandy 2. Surface colors, chroma 2 or less Central Basin No Series Available Fine-silty, Typic Sulfaquents 1. Sulfidic materials 2. Finer textured 3. Fluid (n value >0.7) 4. Moderate organic C contents 194 mainland cove, and transition zone landscape units had very small quantities of monosulfides and disulfides within their profiles, whereas remaining landscape units contained soils that had higher quantities of monosulfides and disulfides within the profile. Demas (1998) did not incubate the samples to determine the presence or absence or sulfidic materials as prescribed in Soil Taxonomy. Rather he measured the quantity of monosulfides and disulfides in the soils and inferred from these data which soils contained ?sulfidic materials?. Another observation of Demas (1998) was that many soils in the deep mainland coves contained buried organic horizons within 100 cm of the soil surface. These buried organic horizons likely represent former tidal marshes that were submerged by rising sea levels during the Holocene. What Demas termed the central basin was the largest landscape unit in Sinepuxent Bay, but the soils were not studied in as much detail as the other landforms. The single pedon sampled by Demas (1998) in this unit contained disulfides within the profile. This low-energy environment possessed the ideal combination of factors to facilitate sulfide mineral formation, including an anaerobic environment, a source of SO 4 2- , fresh organic matter (in the form of algal detritus), an iron source (iron oxides sorbed to mineral sediments), and sulfate reducing bacteria (Ponnamperuma, 1972; Rickard, 1973; Pons et al., 1982). Bradley and Stolt (2003) examined the subaqueous soil-landscape relationships of Ninigret Pond, RI and identified 12 distinct landforms. The dominant soils (presented as subgroups of Soil Taxonomy) associated with each of the landforms they identified are presented in Table 5-2. From their study more suitable and descriptive landform terms were developed from marine geological terms, such 195 Table 5-2. Major landforms and the associated soils found in Ninigret Pond, Rhode Island (summarized from Bradley and Stolt, 2003). Landscape Unit Classification (Soil Taxonomy) Distinctive Soil Properties Lagoon Bottom Typic Hydraquent 1. Fine textures (SiL, SiCL, fSL) 2. Fluid (n values > 1) 3. High organic C contents Storm-surge Washover Fan Flat Typic Sulfaquent 1. Sandy (fS, S) 2. Sulfidic materials 3. Low organic C contents Flood-tidal Delta Flat Typic Psammaquent 1. Sandy (fS, S) 2. Low organic C contents Storm-surge Washover Fan Slope Typic Fluvaquent 1. Buried A horizons in the profile 2. Irregular organic C distribution Flood-tidal Delta Slope Typic Fluvaquent 1. Buried A horizons in the profile 2. Irregular organic C distribution Mainland Submerged Beach Typic Endoaquent 1. Sandy (LS, coS), with coarse fragments 2. Surface contains iron mono-sulfide coatings 3. Low organic C contents Barrier Cove Typic Sulfaquent 1. Sulfidic materials 2. Finer textured Mainland Shallow Cove Typic Endoaquent 1. Thin estuarine deposits, dominated by glaciofluvial parent materials Mid-lagoon Channel Typic Endoaquent 1. Sandy (LS, coS), with coarse fragments 2. Surface contains iron mono-sulfide coatings 3. Low organic C contents Barrier Submerged Beach Typic Endoaquent 1. Sandy (LS, coS), with coarse fragments 2. Surface contains iron mono-sulfide coatings 3. Low organic C contents Shoal Typic Endoaquent 1. Sandy (LS, coS), with coarse fragments 2. Surface contains iron mono-sulfide coatings 3. Low organic C contents Mainland Cove Thapto-Histic Hydraquent 1. Buried organic horizon within the upper 100 cm of the soil surface; both freshwater and salt water marsh origins 2. Mostly SiL, fSL, and LS textures 196 as storm-surge washover fan flats to replace the ?overwash fans? described by Demas (1998). Their work also examined what Demas (1998) called ?transitional zones? and provided landform names, such as storm-surge washover fan slopes, and conceptualized the formation of the soils on these units. Bradley and Stolt (2003) also identified the broader extent of the sulfidic materials in coastal lagoons, especially recognizing sulfidic materials in sandy soils, such as those located on the storm-surge washover fan flats. They also examined the lagoon bottom in greater detail, although the properties of these soils were similar to those previously described by Demas (1998). One major difference, however, was that in Ninigret Pond, RI, soils in the lagoon bottom did not contain sulfidic materials even though the conditions seemed appropriate for sulfide mineral formation. It is not clear whether this results from a lack of sulfides or the presence of carbonate that can neutralize the acidity from oxidation of sulfides. Buried organic horizons were also described within the mainland coves similar to those described in Sinepuxent Bay, MD. They identified and described soils on several newly identified landforms, including the mainland submerged beaches, flood-tidal delta flats, flood-tidal delta slopes, barrier coves, mid- lagoon channel, and barrier submerged beaches. Flood-tidal delta landforms are associated with active inlets into the lagoon. These landforms are sinks of sand-sized particles that are carried into the lagoon during the daily flood tides. These are very active areas where the tidal currents continuously winnow out fine and organic materials and supplies oxygenated water to the sediments. Therefore the conditions needed for sulfide minerals to form are not present in these environments. The barrier cove landforms of Bradley and Stolt (2001) contain soils that are similar to the lagoon 197 bottom, except these soils do contain sulfidic materials. Osher and Flannagan (2007) studied the subaqueous soil-landscape relationships in a mesotidal estuary in Maine. Different processes have shaped the landforms and soils located in Taunton Bay, due to the absence of a barrier island system that was present in the coastal lagoons previously studied (Demas, 1998; Bradley and Stolt, 2001) and a greater tidal range. Seven subaqueous landforms were identified and the following names were applied: terrestrial edge, coastal cove, submerged fluvial stream, mussel shoal, fluvial marine terrace, channel shoulder, and channel. The dominant soils and the associated landforms in Taunton Bay are presented in Table 5-3. Although, these landforms were different from those described in previous studies, similar processes and soils were described. For example, on the terrestrial edge landform, several different soils were identified, but generally these soils were composed of recently deposited estuarine materials overlying buried subaerial soils. The submerged marsh map unit contained soils that have buried organic horizons deeper than 100 cm below the soil surface that overlie subaerial soil horizons and contained sulfidic materials within the upper portion of the profile. The submerged marsh soils were similar to those described in the Sinepuxent Bay, MD, mainland coves (Demas, 1998). The fluvial marine terrace was a landform that supports soils similar to those found in the lagoon bottoms described in Sinepuxent Bay, MD in that these soils found in low-energy environments, were fine textured and contain sulfidic materials within the profile. The channel shoulder landform was adjacent to the fluvial marine bottom and the soils on the channel shoulder were similar to those on the fluvial marine bottom except in areas where the 198 Table 5-3. Major landforms and associated soils found in Taunton Bay, Maine (summarized from Osher and Flannagan, 2007). Landscape Unit Soil Map Unit Classification (Soil Taxonomy) Distinctive Soil Properties Terrestrial Edge Submerged Marsh Fine-silty, Typic Sulfaquents 1. Buried organic horizons deeper than 1m below the soil surface 2. Buried subaerial soils below the organic horizons 3. Fine textured (sicl) Submerged Beach Coarse-loamy, Haplic Sulfaquents 1. Sulfidic materials 2. SiL, SL, and S textures Submerged Fluvial Delta Sandy, Haplic Sulfaquents 1. Sulfidic materials 2. SiL textures over S and LcoS textures 3. Low organic C contents Terrestrial Edge Coarse-loamy, Sulfic Endoaquents 1. Sulfidic materials 2. SiL textures Coastal Cove Shallow Coastal Cove Coarse-loamy, Haplic Sulfaquents 1. Sulfidic materials 2. L textures Deep Coastal Cove Coarse-silty, Typic Sulfaquents 1. Sulfidic materials 2. L and SiL textures Submerged Fluvial Stream Submerged Fluvial Stream Fine-silty, Typic Sulfaquents 1. Sulfidic materials 2. SiL textures 3. High organic C contents Mussel Shoal Mussel Shoal Fine-silty, Typic Sulfaquents 1. Sulfidic materials 2. Very shelly surface 3. Si and SiL textures Fluvial Marine Terrace Fluvial Marine Terrace Fine-silty, Typic Sulfaquents 1.Sulfidic materials 2. SiL and SiCL textures Channel Shoulder Channel Shoulder Fine-silty, Typic Endoaquents 1. Monosulfides present to 35 cm below the soil surface 2. SiL textures, some horizons are very shelly Channel 199 vegetative cover exceeds 50%. Those areas covered by vegetation supported soils that did not contain sulfidic materials within the profile and were similar to the lagoon bottom soils in Ninigret Pond, RI. Osher and Flannagan (2007) hypothesized that the soils formed under a vegetative cover differed from the non-vegetated soils due to differences in soil chemistry resulting from oxygen transport by the growing vegetation which precluded the formation of sulfide minerals. It is not clear, however, why and how the shallow zone oxygenated by SAV roots should inhibit the formation of sulfide minerals at greater depths. Coppock et al.(2004) studied the subaqueous soil-landscape relationships in Rehoboth Bay, DE, which is a microtidal estuary. He identified landforms similar to those of Demas (1998) and Bradley and Stolt (2003), but identified one new landform which he called a fluviomarine bottom. The fluviomarine bottom lay within the mouth of a fresh water stream entering the brackish estuary or lagoon where the subaqueous soils develop from mixed fluvial and marine sediments as the river-borne sediments flocculate and settle as they encounter the brackish water. The soils were very fluid (n values > or >> 1), fine textured (SiCL, CL, SiC, or C) with high organic carbon levels, and have sulfidic materials within the profile. Studies to date have examined subaqueous soil-landscape relationships in relatively small coastal lagoons or estuaries (mostly between 120 to 6,000 ha with the largest being (the 6,000 ha) Rehoboth Bay, DE). My intention was to determine the suitability of the current models within the framework of a larger coastal system. The objectives of this study were 1) to evaluate the suitability of existing subaqueous soil- landscape models from Atlantic coastal lagoons and estuaries in describing the 200 distribution of the soils of Chincoteague Bay; 2) to modify or enhance those soil- landscape models as needed to accommodate observations in Chincoteague Bay; and 3) to conduct a soil resource inventory of Chincoteague Bay. Materials and Methods Study Site Chincoteague Bay is the largest of Maryland?s inland coastal lagoons with an area of 19,000 ha that formed as a result of sea level rise following the last glacial period and the consequent flooding of low-lying areas. This coastal lagoon is bounded by Assateague Island to the east and the Maryland mainland to the west and is connected to the Atlantic Ocean by the Ocean City inlet to the north and the Chincoteague inlet to the south (approximately 52 km apart). Chincoteague Bay is classified as a microtidal (tidal range < 2 m) lagoon with an average daily tidal range of 10-20 cm near Public Landing, MD. Generally the water depths are less than 2.5 m throughout the bay. Salinity within Chincoteague Bay changes seasonally, from 26 to 34 ppt with the highest salinity values occurring in the summer due to high evaporation rates, poor circulation, and limited fresh water inputs (Wells and Conkwright, 1999). The soils surrounding Chincoteague Bay have formed from alluvium, aeolian sand, organic materials, and marine sediments (Worcester County Soil Survey). Sediment enters the lagoon through tidal inlets, tidal creeks, shoreline erosion, storm-surge overwash events on the barrier island, and aeolian transport (Bartberger, 1976). 201 Soil Sampling Techniques and Laboratory Analysis Base maps, such as a detailed bathymetric map and high resolution false-color infrared photography of Chincoteague Bay, were used to delineate the subaqueous landscape units (USDA-NRCS, 2001). The different landscape units were delineated based on slope, water depth, landscape shape, depositional environment, and geographic proximity to other units (Chapter 3). The high resolution orthomosaic photograph used in Figures 5-1, 5-2, 5-3, 5-6, 5-7, 5-8, 5-9, 5-10, 5-11, 5-12 was provided by USDA-NRCS Geospatial Data Branch in Fort Worth, TX (USDA- NRCS, 2001). The soils were examined at multiple locations within each landscape unit. Pedon locations and their associated landforms are shown in Figure 5-1. The sites were chosen to document the composition and variability within each landscape unit and to determine the differences or similarities between adjacent units. Pedons along two additional transects (consisting of 10 observations each) were described in the adjacent mainland marshes. These descriptions were collected to determine the depths at which organic horizons occurred in these marshes, which were to be compared with similar features described in adjacent subaqueous soils. The soils were accessed by boat and locations where soils were described and sampled were recorded using a global positioning unit (GPS). One-hundred and forty six soils were examined using a vibracorer or a McCauley peat sampler and profiles were described on the boat according to the National Soil Survey Center guidelines (Schoeneberger et al., 2002). Samples from 86 of the pedons were collected for further laboratory analyses. Methods of handling and analyses of samples are presented in Chapter 4. 202 Figure 5-1. Location map of the subaqueous soil profiles described in Chincoteague Bay and the subaqueous landscape units they occupy. 203 Soil-Landscape Analysis After characterization, the soils were classified to the series level according to the Keys to Soil Taxonomy (Soil Survey Staff, 2006) and proposed amendments to Soil Taxonomy (Northeast Regional Cooperative Soil Survey Subaqueous Soils Committee, 2007). Eight new series were proposed to accommodate soils of significant extent that did not fall within the range of characteristics for previously established series (Chapter 4). Existing soil-landscape models were compared with observations from Chincoteague Bay. Where the models were partially adequate, they were utilized and enhanced to accommodate the soils identified in Chincoteague Bay and where they were inadequate or non-existing, new concepts were developed for those landforms. Once the soil-landscape models were developed for Chincoteague Bay, a soil resource inventory (map) was developed. Development of Soils Map A first attempt at gathering soils information can be obtained for a particular area by collecting geomorphic maps, high quality aerial photography, and established soil-landscape models for the region. A preconceived notion of what types of soils to expect is based upon established soil-landscape models. This is the fundamental principle of the pedologic paradigm (Hudson, 1990). Initially soil boundaries are based on landforms (geomorphic maps). These boundaries are checked by collecting information on the soils across the landforms and boundaries to confirm the soil properties and systematic changes (Schaetzl and Anderson, 2005). This process leads to confirming the lines, adding new lines, or aggregating landforms together. In subaerial settings, changes in topography (slope curvature, steepness, or aspect) affect 204 which soils can exist at a site and soils can be identified on terrain alone (Moore et al., 1993). In subaqueous settings the slope is very subtle and is not as useful in identification of landforms and soils. However, water depth and depositional environments are more useful in the identification of particular soils. Results Subaqueous Soil-Landscape Relationships In Chincoteague Bay, 10 major landforms were identified (Chapter 3). These were storm-surge washover fan flats, storm-surge washover fan slope, paleo-flood tidal delta, barrier cove, dredged shoal, lagoon bottom, fluviomarine bottom, mainland cove, and submerged wave-cut headland. Each of these ten landforms and their associated soils will be discussed, starting on the barrier island side of the lagoon and migrating westward toward the mainland shore of Chincoteague Bay. The dominant soils associated with each landform are presented in Table 5-4. The soils of the storm-surge washover fan flat were formed in extremely sandy materials transported by overwash events on the adjacent barrier island. These landscapes were located in shallow water and were influenced by wave action. These soils have high fine sand contents (Table 5-5) and generally lack discontinuities (vertical uniformity), which resulted from the material being derived entirely from the subaerial soils on the barrier island, and carried during high-energy overwash events. In these landscape units finer grained materials (silts and clays) were essentially absent, because of high-energy deposition and winnowing by wind generated waves (Wells and Conkwright, 1999). The soils on this landform were characterized by 205 Table 5-4. Classification of subaqueous soil profiles in each Chincoteague Bay landform. All profiles classified according to the Proposed Changes to Soil Taxonomy (Northeast Regional Cooperative Soil Survey Subaqueous Soils Committee, 2007). Landform Name # Profiles (Total) Classification (Proposed Soil Taxonomy) # Observations (Percentage) Barrier Cove 8 Fine-silty, Typic Sulfiwassents Sandy, Haplic Sulfiwassents Sulfic Psammowassents 6 (75%) 1 (12.5%) 1 (12.5%) Dredged Channel 0 Dredged Shoal 7 Sulfic Psammowassents Coarse-loamy, Haplic Sulfiwassents Fine-loamy, Typic Sulfiwassents 5 (71%) 1 (14.5% 1 (14.5%) Fluviomarine Bottom 15 Fine-silty, Typic Sulfiwassents Fine-loamy, Typic Sulfiwassents Coarse-loamy, Aeric Sulfiwassents 13 (87%) 1 (6.5%) 1 (6.5%) Lagoon Bottom 51 Fine-silty, Typic Sulfiwassents Fine-loamy, Typic Sulfiwassents Coarse-loamy, Haplic Sulfiwassents Coarse-loamy, Typic Sulfiwassents Fine-loamy, Haplic Sulfiwassents Sandy, Haplic Sulfiwassents Coarse-silty, Sulfic Haplowassents Fine-silty, Fluvic Sulfiwassents Sulfic Psammowassents Fine-loamy, Thapto-Histic Sulfiwassents 35 (67%) 3 (6%) 3 (6%) 2 (4%) 2 (4%) 2 (4%) 1 (2%) 1 (2%) 1 (2%) 1 (2%) Mainland Cove 24 Fine-silty, Typic Sulfiwassents Fine-loamy, Typic Sulfiwassents Coarse-loamy, Haplic Sulfiwassents Coarse-loamy, Typic Sulfiwassents Coarse-loamy, Aeric Sulfiwassents Fine, Haplic Sulfiwassents Sandy, Haplic Sulfiwassents Coarse-silty, Thapto-histic Sulfiwassents Fine-silty, Thapto-histic Sulfiwassents 13 (54%) 3 (13%) 2 (8%) 1 (4%) 1 (4%) 1 (4%) 1 (4%) 1 (4%) 1 (4%) Paleo-Flood Tidal Delta 3 Sulfic Psammowassents Sandy, Haplic Sulfiwassents 2 (67%) 1 (33%) 206 Table 5-4. Continued. Landform Name # Profiles (Total) Classification (Proposed Soil Taxonomy) # Observations (Percentage) Storm-surge Washover Fan Flat 13 Sulfic Psammowassents Sandy, Haplic Sulfiwassents Coarse-loamy, Haplic Sulfiwassents Sandy over loamy, Haplic Sulfiwassents 7 (54%) 3 (23%) 2 (15%) 1 (8%) Storm-surge Washover Fan Slope 8 Sulfic Psammowassents Sandy, Haplic Sulfiwassents Coarse-loamy, Haplic Sulfiwassents Coarse-loamy, Typic Sulfiwassents Fine-silty, Typic Sulfiwassents 3 (37.5%) 2 (25%) 1 (12.5%) 1 (12.5%) 1 (12.5%) Submerged Wave-cut Headland 16 Fine-silty, Typic Sulfiwassents Coarse-loamy, Haplic Sulfiwassents Sapric Sulfiwassists Fine-loamy, Thapto-histic Sulfiwassents Sulfic Psammowassents Fine, Thapto-histic Sulfiwassents Coarse-loamy, Typic Sulfiwassents Fine-loamy, Typic Sulfiwassents 5 (31%) 3 (19%) 2 (12.5%) 2 (12.5%) 1 (6%) 1 (6%) 1 (6%) 1 (6%) 207 gleyed colors (N-5GY, value 2.5-5, chroma 0-1) and sandy textures (fS, LfS, fSL, or SL). They were non-fluid (n values <0.7), and contained sulfidic materials within the profile. Most pedons had a thick (2 to 12 cm) oxidized surface horizon that was slightly yellower and a unit higher in value and chroma (5Y 4/1) than the underlying horizons. Most pedons contained fragments of partially decomposed organic materials associated with the seagrasses that commonly inhabit these soils. Organic carbon contents ranged from 0.22 to 5.59 g kg -1 . Most of the pedons had noticeable hydrogen sulfide odor. The storm-surge washover fan slope landform had the greatest slopes observed within the bay, ranging from 0.1 to 0.3%. This landform was located in deeper water than the fan flats and therefore there was decreased wave agitation and increased tidal current influence. The soils were composed of sandy materials transported by overwash events in the upper part, but also had a lithologic discontinuity, below which we found finer textured lagoon bottom sediments. These soils were characterized by gleyed colors (10Y-5GY, values 2.5-4, chroma 0-1) and sandy or loamy textures (SL, fSL, fS, LfS, or L). They were non-fluid to slightly fluid (n values 0.7 to 1) and contained sulfidic materials in the profile. Most pedons had an oxidized surface horizon (1 to 6 cm thick) that was slightly yellower and a unit higher in value and chroma than the underlying horizons. Most pedons contain organic fragments, which were deposited in these profiles from wave erosion of the adjacent flats. Organic carbon contents ranged from 0.38 to 8.84 g kg -1 , with the higher contents occurring deeper in the profile associated with the finer textured sediments. 208 Table 5-5. Weighted fine sand content (0-50 cm) for the subaqueous soil profiles located on the storm-surge washover fan flats. Sample Average % fS (upper 50 cm) Weighted % fS (upper 50 cm) CB01 57.5 57.1 CB17 64.5 65.9 CB45 90.6 91.0 CB56 79.5 89.1 209 Soils of the paleo-flood tidal delta were dominated by sandy materials that were transported into the bay when the Green Run Inlet was active, and since its closure sandy materials have continued to be deposited by washover events from the barrier island. These soils were characterized by dark gray colors (5Y-10Y, values 2.5-4, chroma 0-1) and sandy textures (SL, LfS, fS, or coS). They were non-fluid (n values <0.7) and contained sulfidic materials in the profile. Most pedons had oxidized surface horizons (2 to 7 cm thick) that were slightly yellower and a unit higher in value and chroma than the underlying horizons. Most pedons contained organic fragments, which were deposited in these profiles from wave erosion of the adjacent barrier island marshes or seagrass beds on the washover flats. Organic carbon contents ranged from 0.47 to 3.25 g kg -1 , with the highest contents occurring in the surface horizons. The barrier coves were low-energy environments located in embayments or protected areas adjacent to the barrier island. These low-energy environments allowed finer textured suspended materials to accumulate, although these soils showed influence of washover events that created sandy surfaces on many of the soil profiles. Most of the soils had a lithologic discontinuity with sandy loam textures below the finer texture materials, which probably reflect the relict flood tidal delta sediments that were deposited when the Green Run Inlet was active. These soils were characterized by gleyed colors (N-10Y, values 2.5-4, chroma 0-1) with a yellower (5Y 4/1) oxidized surface horizon. They were loamy textured (fSL, L, SiCL, or CL) and contained sulfidic materials within the profile. Most pedons contained organic fragments, deposited in these profiles from wave erosion of the adjacent island 210 marshes found within the barrier coves and from adjacent seagrass beds. Organic carbon contents ranged from 1.75 to 61.90 g kg -1 , with the lower values occurring closer to the barrier island and deeper in the profile. The highest values occurred in the upper 75 cm of the soil profile. Dredged shoals were created during the dredging of a shipping channel and the dredging associated with a channel marker located in the southern portion of the bay. These soils were characterized by gleyed colors (N-5GY, value 2.5-6, chroma 0- 1) with thin (2 cm) oxidized surface horizons (5Y 4/1) and sandy textures (S, LS, or SL). They are non-fluid (n values <0.7) and contain sulfidic materials within the profile. The sandy material in these soils was derived from overwash on the barrier island and relict materials when Sinepuxent Inlet was active. The pedons located on the dredge shoal in the middle of the lagoon bottom contain soils that were loamy textured and were more similar to the surrounding soils on the barrier island side of the lagoon bottom. The lagoon bottom is a deep water, central, low-energy, depositional landform. This landform is dominated by tidal currents, but the > 2.0 m water depth and wide expanse of the landform reduced their impact and made the wind generated wave agitation negligible. The soils of the lagoon bottom were moderately fluid (n value >1) and fine textured throughout. These soils were characterized by gleyed colors (10Y-10GY, value 2.5-5 (mostly <4), chroma 0-1) with a very thin (1 to 2 cm) oxidized surface horizon (5Y 4/1), have loamy (SiCL, CL, SiL, or L) textures, and contained sulfidic materials throughout the profile. Most pedons had horizons that contained organic fragments and shell fragments (identifiable shells include razor 211 clams, oyster, gastropod, and mussel). Organic carbon contents ranged from 0.93 to 31.47 g kg -1 , with the lower values occurring in coarser textured materials. Along the barrier island side of the lagoon bottom, the upper portion of the soil profiles were composed of sandier materials that overlie finer textured materials at depth. The sandier nature of the upper parts of these profiles was likely the result of increased delivery of coarse particles out into the bay during storm events with higher energies. Several soil profiles located adjacent to the paleo-flood tidal delta were coarse textured throughout, which may have resulted from similar storm events discharging coarser materials farther into the bay. Along the mainland side of the lagoon bottom several soil profiles contained buried organic horizons that generally occurred deeper than 1m below the soil surface, and which were similar to soils further to the west, closer to the mainland. In the southern portion of the mainland side of the lagoon bottom, several soil profiles had thin horizons (14 to 40 cm thick) composed of sandy loam textures at or near the soil surface. These areas were associated with numerous islands, which were eroding, creating the source of these coarser sediments (Wells and Conkwright, 1999). The fluviomarine bottoms are low-energy environments that lay within the mouth of an incoming stream. The soils of the fluviomarine bottom were moderately to very fluid (n values > or >>1) and fine textured (SiCL or CL) throughout. Due to the very fluid nature of these soils they have a very low bearing capacity. These soils were characterized by gleyed colors (N-5GY, value 2.5-4, chroma 0-1) with thin (1 to 3 cm) oxidized surface horizons and contained sulfidic materials. Most pedons contained horizons with up to 40% organic fragments (by volume) from the adjacent 212 mainland marshes and marsh islands in the landform. Organic carbon contents ranged from 4.90 to 20.98 g kg -1 . Along Mills Island there are two pedons that were a little coarser (SL, L or fS) and these soils may be part of a submerged mainland beach. One of the profiles contained horizons with brighter matrix color of chroma 3 deeper in the profile (75 to 116 cm) which may represent relict subaerial soil features or may possibly be related to the upwelling of oxygenated groundwater into the bay (Dillow et al., 2002). Mainland coves were located along the western (mainland) shore and are deeper, low-energy depositional areas. Due to the combination of a low-energy environment and the adjacent tidal marshes, these soils were generally composed of silts and clays with higher amounts of organic matter. Several profiles contained buried organic horizons that occur between 56 and 198 cm below the soil surface. Many of these buried organic horizons were underlain by soil horizons thought to be originally associated with subaerial soils (described as Ab, BAgb, Btgb, or Cgb). These horizons may contain redoximorphic features, soil structure, or a low salinity, which were indicative of an upland environment. These soil profiles usually contained a least one discontinuity in the profile, and generally sandier materials underlie the buried organic horizons. These soils were characterized by gleyed colors (2.5Y-5GY, values 2.5-6, chroma 0-1) and loamy textures (SiCL, CL, L, SiL, or fSL). They were slightly fluid to moderately fluid (n values >0.7), and contained sulfidic materials. Most pedons contained organic fragments, which may have been transported into the coves by wave erosion of the adjacent tidal marshes. Organic carbon contents ranged from 2.52 to 221.75 g kg -1 , with the highest values in the 213 buried organic horizons. The pedons close to the mainland generally had lower porewater salinity levels with depth. The soils that did not contain buried organic horizons were fine textured and were similar to the soils described on the lagoon bottom landform. The submerged wave-cut headlands were gently sloping, erosional landforms adjacent to the mainland coast. Most pedons contained buried organic horizons that occurred between 18 and 161 cm below the soil surface. Many of these buried organic horizons were underlain by soil horizons formed in subaerial environments, such as Ab, BAgb, or Cgb. These horizons were characterized by redoximorphic features or low salinity levels indicative of formation in an upland environment. The soils on these landforms were generally characterized by gleyed colors (N-5GY, values 2.5-5, chroma 0-1), loamy textures (SiCL, CL, L, fSL, SL, LS, or fS), and contained sulfidic materials. Organic carbon contents ranged from 2.76 to 266.80 g kg -1 , with the higher values being associated with buried organic horizons. The pedons close to the mainland generally had lower porewater salinity levels with depth. Several soil pedons that did not contain organic horizons were fine textured and fluid throughout and were similar to the soils located on the lagoon bottom, although these pedons have sandier textured surface horizons. Buried Organic Soils Several buried organic rich horizons were described along the mainland side of the bay, and were located within mainland cove, submerged wave-cut headland, and lagoon bottom landforms. Similar buried O horizons have also been identified in mainland coves in other Atlantic estuaries, such as Sinepuxent Bay, MD, Ninigret 214 Pond, RI, and Taunton Bay, ME (Demas and Rabenhorst 1998; Bradley and Stolt, 2003; Osher and Flannagan, 2007). These paleosols are likely of late Holocene age and were buried by recent estuarine sediments that ranged in thickness from 28 to 198 cm. The overlying water depths ranged from 20 to 250 cm, depending on the distance from the mainland coast. These soils were classified as Sapric Sulfiwassists, Thapto- histic Sulfiwassents, or Typic Sulfiwassents depending on the thickness of the overlying estuarine soil material. In general, buried horizons occurred at shallower depths in profiles closer to the mainland and at greater depths when the pedon was located farther from the shoreline. This relationship was explored further by making two transects from the mainland coast into the adjacent marshes. The transects are shown in Figures 5-2 and 5-3. During the Pleistocene glaciation the sea level was over 100 m shallower than at present (Biggs, 1973). At the end of the Pleistocene as glaciers began to melt and recede, sea levels began to rise and caused submergence of coastlines. The rates of sea level rise during the early to mid Holocene (12,000 to 4,000 yr BP) was rapid (Bloom and Stuvier, 1963), but the rate of sea level rise began to slow to a rate of approximately 1 mm yr -1 (Redfield and Rubin, 1962), which allowed colonization of the tidal mud flats by salt tolerant vegetation (Bloom and Stuvier, 1963; Redfield, 1972). Therefore, it was likely that the tidal marshes along the mainland side of Chincoteague Bay began to form around 4,000 to 5,000 yr BP. These marshes grow and function at or near sea level and the thickness of the accumulated organic horizons were dependent on sea level rise and the associated marsh accretion. If for some reason the marsh failed to keep up with sea level rise, it became permanently 215 Figure 5-2. Location of described pedons located along transect 1 from the adjacent tidal marsh into Chincoteague Bay. 216 Figure 5-3. Location of described pedons located along transect 2 from the adjacent tidal marsh into Chincoteague Bay. 217 inundated and submerged. The marsh surfaces found buried within the soils along mainland side of the bay were the result of marsh submergence due to sea level rise. The radiocarbon in the buried marsh horizons reflects the date when those horizons were at or near sea level. Therefore, by obtaining radiocarbon age and elevation of the buried marsh surfaces we could estimate rates of average sea level rise during the intervening period. However, in these marsh ecosystems, organic matter has been altered over time due to decomposition and compression under its own weight causing consolidation of the layers and increases in bulk density (Kearney and Ward, 1986). The autocompaction of the deeper organic-rich layers shifts downward from the original position of the organic horizon leading to apparent higher rates of marsh accretion or erroneous high values of sea level rise (Craft and Richardson, 1998). This can be avoided by selecting basal peat samples that are collected above dense, low n value, submerged mineral soil surfaces (Hussein et al., 2004). With the depth of the organic horizons being deeper than their original position, the calculated average sea level rise rates would be higher than values based on basal peat radiocarbon dates. Carbon-14 dates from five buried organic horizons are reported in Table 5-6. Dates were obtained from samples collected along transects described earlier and are shown in Figures 5-4 and 5-5. Based on the carbon age and the elevation of the current marsh surface the average rate of sea level rise in the intervening period ranged from 1.24 to 1.55 mm yr -1 . These rates were similar to the rates of relative sea level rise of 2.0 to 4.0 mm yr -1 reported by others for the Chesapeake Bay region (Hick et al., 1983; Rabenhorst and Griffin, 1989). Using a date collected by Demas (1998) from a wood sample in an organic horizon located in the deep mainland cove 218 Figure 5-4. Soil profiles described on transect 1. Carbon-14 dates for two buried organic horizons. 219 Figure 5-5. Soil profiles described on transect 2. Carbon-14 dates for three buried organic horizons. 220 landform (Table 5-5), the calculated average sea level rise rate was 1.8 mm yr -1 , which (was slightly greater than the rates obtained from our study but was still within in the range of rates reported for the Mid-Atlantic region. Two dates collected by Hussein (1996) in Hell Hook Marsh (Dorchester County), MD, from estuarine peat samples (Table 5-6) provided rates of 1.44 to 1.52 mm yr -1 , which were also similar to rates obtained from our study. However, these samples were not basal peats and therefore had likely undergone autocompaction, which may generate higher rates of sea level rise. In contrast, rates collected from a series of basal peats in Hell Hook Marsh and Cedar Creek Marsh (Dorchester County), MD, yielded average rates of sea level rise over the last 2000 years of 0.5 to 1.0 mm per year (Hussein et al., 2004). Soil Map Unit Composition and Variability A soil map unit is a collection of areas (delineations) that contain the same soil components (Soil Survey Division Staff, 1993). A soil map unit is usually named for the dominant component (soil series), but it also contains other soil components that are included in the map unit due to the scale of mapping and the natural variability within the map unit (Soil Survey Division Staff, 1993). Thirteen soil map units were designated for the study area and are listed in Table 5-7. The soil map unit symbol consists of two letters that represent the dominant soil series (used in the map unit name) followed by a Greek symbol indicating the depth of water (at mean sea level). The water depth classes used for the map unit symbol are as follows: ? is 0.2 to 1.0 m; ? is 1.0 to 1.5 m; ? is 1.5 to 2.0 m; ? is 2.0 to 2.5 m. The map name includes the dominant soil series for which the unit is named, the dominant surface texture, and the range of water depths located in the unit. The surface textures of the 146 221 Table 5-6. Carbon-14 dates for four buried organic horizons located in Chincoteague Bay, one buried organic horizon located in an adjacent tidal marsh area, one wood fragment from adjacent Sinepuxent Bay, MD (Demas and Rabenhorst, 1999), and two peats from Hell Hook Marsh and Cedar Creek Marsh (Dorchester County), MD (Hussein, 1996). Average sea level rise rates were also calculated for these horizons. Pedon Sample Water Depth (MSL) (mm) Depth Below Soil Surface (mm) Total Depth Below MSL (mm) Age (B.P.) Long-Term Average Sea Level Rise (mm yr -1 ) CB21 Oab 1730 180 1910 1530?60 1.25 CB97 Oab1 2200 1950 4150 3280?70 1.27 CB136 Oab1 1650 1610 3260 2100?50 1.55 CB142 Oab 2000 1000 3000 2420?60 1.24 M08 Oab NA 2030 NA 1890?50 1.07 Demas (1999) Wood Fragment 1000 1500 2500 1430?60 1.80 Hussein (1996) Peat NA 2500 NA 1740 1.44 Hussein (1996) Peat NA 3030 NA 2000 1.52 222 Figure 5-6. Surface textures of soil profiles described in Chincoteague Bay. 223 soil pedons described in Chincoteague Bay are shown in Figure 5-6. The soil map unit delineations are presented in Figure 5-7. The composition of each of the 13 soil map units is presented in Table 5-8. The location of pedons classified to the family level of Soil Taxonomy and their corresponding soil map units are shown in Figure 5-8. The location of pedons classified to the series level of Soil Taxonomy and their corresponding map units are shown in Figure 5-9. Below is a short narrative description of each of the 13 subaqueous soil map units used in Chincoteague Bay. Coards silty clay loam, 1.0 to 1.5 m MSL (Co?) ? This unit consists of very deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur on the fluviomarine bottom in the southeastern portion of the bay. They formed in mixed fluvial and lagoonal sediments. The Coards and similar soils (80%) are finer textured (SiCL or CL), moderately to very fluid (n values > or >> 1), with moderately high organic carbon levels and sulfidic materials. Contrasting soils (20%) are loamy textured soils, soils with buried organic horizons deeper than 100 cm below the soil surface (located mainly at the eastern edge near a marsh island), or are coarse textured soils that contain redoximorphic features within the upper 100 cm of the soil surface. Cottman sand, 1.5 to 2.0 m MSL (Ct?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.5 to 2.0 m of water (MSL). These soils occur on the barrier island side of the lagoon bottom. They formed in mixed lagoonal and barrier island dune sediments. The Cottman and similar soils are coarse textured (sandy loams, loamy sands, and sands), that are non-fluid (n values <0.7) or slightly fluid (n values from 0.7 to 1), with moderately low organic carbon contents and 224 Table 5-7. Subaqueous Soil Mapping Legend for Chincoteague Bay, Maryland. Map Unit Symbol Map Unit Name Co? ? Coards silty clay loam, 1.0 to 1.5 m depth Ct? Cottman sand, 1.5 to 2.0 m depth De? Demas fine sand, 0.2 to 1.0 m depth De? Demas fine sand, 1.0 to 1.5 m depth Dm? Demas sandy loam, 1.0 to 1.5 m depth Mm? Middlemoor sandy loam, 0.2 to 1.0 m depth Mm? Middlemoor sandy loam, 1.0 to 1.5 m depth Si? Sinepuxent loam, 1.0 to 1.5 m depth Sp? Southpoint silty clay loam, 1.0 to 1.5 m depth Tg? Tingles silty clay loam, 1.0 to 1.5 m depth Tg? Tingles silty clay loam, 2.0 to 2.5 m depth Th? Thorofare sandy loam, 1.0 to 1.5 m depth Tr? Truitt silty clay loam, 0.2 to 1.0 m depth ? Water depth symbols: ?- 0.2 to 1.0 m below MSL; ?- 1.0 to 1.5 m below MSL; ?- 1.5 to 2.0 m below MSL; and ?- 2.0 to 2.5 m below MSL. 225 Figure 5-7. Subaqueous soil map of Chincoteague Bay. The legend for this map is given in Table 5-7. 226 Figure 5-8. Location map of described pedons classified to the family level of Soil Taxonomy and the corresponding soil map units. 227 Table 5-8. Soil taxonomic classifications and components of each of the 10 soil map units identified in Chincoteague Bay. Map Unit # Profiles (Total) Series # Observations (percentage) Co? 15 Coards ? Tingles ? Figgs Truitt Unnamed C 11 (72%) 1 (7%) 1 (7%) 1 (7%) 1 (7%) Ct? 7 Cottman ? Thorofare ? Demas ? Sinepuxent 3 (43%) 2 (29%) 1 (14%) 1 (14%) De? 10 Demas ? Thorofare ? Cottman ? Tizzard 5 (50%) 2 (20%) 2 (20%) 1 (10%) De? 7 Demas? Cottman? Figgs 5 (72%) 1 (14%) 1 (14%) Dm? 3 Demas ? Thorofare ? 2 (67%) 1 (33%) Mm? 5 Middlemoor ? Tingles ? Demas 2 (40%) 2 (40%) 1 (20%) Mm? 3 Middlemoor Thorofare 2 (67%) 1 (33%) Si? 3 Sinepuxent Truitt 2 (67%) 1 (33%) ? Indicates similar soils 228 Table 5-8. Continued. Map Unit # Profiles (Total) Series # Observations (percentage) Sp? 28 Southpoint Tax. ? Southpoint ? Truitt ? Truitt Tax. ? Tumagan ? Tingles Cottman Figgs Unnamed C Middlemoor Demas 8 (29%) 1 (4%) 4 (14%) 1 (4%) 2 (7%) 4 (14%) 2 (7%) 2 (7%) 2 (7%) 1 (4%) 1 (4%) Tg? 10 Tingles Figgs 8 (80%) 2 (20%) Tg? 37 Tingles ? Truitt Truitt Tax. Middlemoor ? Figgs Sinepuxent Southpoint Unnamed B 25 (68%) 3 (8%) 2 (5%) 3 (8%) 1 (3%) 1 (3%) 1 (3%) 1 (3%) Th? 10 Demas ? Thorofare ? Cottman ? Tingles 5 (50%) 3 (30%) 1 (10%) 1 (10%) Tr? 8 Truitt ? Cottman Coards Figgs Middlemoor Southpoint Tax. ? Tingles 1 (12.5%) 2 (25%) 1 (12.5%) 1 (12.5%) 1 (12.5%) 1 (12.5%) 1 (12.5%) ? Indicates similar soils 229 Figure 5-9. Location map of described pedons classified to the series level of Soil Taxonomy and the corresponding soil map units. 230 contain sulfidic materials. Demas fine sand, 0.2 to 1.0 m MSL (De?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 0.2 to 1.0 m of water (MSL). These soils occur mainly on storm-surge washover fan flats. They formed in barrier island dune sediments. The Demas and similar soils are sandy, and non-fluid (n values <0.7), with low organic carbon contents and sulfidic materials. Contrasting soils (10%) are composed of sandy materials that overlay finer textured materials and are located on the edge near the barrier cove landform or in deeper scour channels within the fan flats. Demas fine sand, 1.0 to 1.5 m MSL (De?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur mainly on dredged shoals. They formed in mixed lagoonal and barrier island dune sediments. The Demas and similar soils are sandy, and non-fluid (n values <0.7), with low organic carbon contents and sulfidic materials. Contrasting soils (14%) are located close to the lagoon bottom that formed from lagoonal sediments, and are finer textured throughout. Demas sandy loam, 1.0 to 1.5 m MSL (Dm?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur mainly on paleo-flood tidal deltas. These soils formed from sand-sized particles transported into the bay through a relict inlet overlain by recent barrier island dune sediments. Demas and similar soils are sandy, and non-fluid (n values <0.7), with low organic carbon contents and sulfidic materials. Middlemoor sandy loam, 0.2 to 1.0 m MSL (Mm?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 0.2 to 1.0 m of 231 water (MSL). These soils occur in barrier coves. These soils formed from eroded marsh sediments and lagoonal sediments, which overlay relict flood tidal delta sediments. Middlemoor and similar soils (80%) are finer textured over coarser textured sediments, and are moderately fluid (n value > 1) within the control section, with moderately high organic carbon contents and sulfidic materials. These profiles may also have a cap of recent barrier island dune sediments, depending on their proximity to the barrier island. Contrasting soils (20%) are sandy throughout and are located near the barrier island, thus these profiles reflect a strong influence of the barrier island washover events. Middlemoor sandy loam, 1.0 to 1.5 m MSL (Mm?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur in barrier coves. These soils formed from eroded marsh sediments and lagoonal sediments, which overlay relict flood tidal delta sediments. Middlemoor and similar soils are finer textured (SiL, SiCL, or CL) over coarser textured sediments (fSL or LfS), and are moderately fluid (n value > 1) within the control section, with moderately high organic carbon contents and sulfidic materials. These profiles may also have a cap of recent barrier island dune sediments, depending on their proximity to the barrier island. Contrasting soils (33%) are sandy throughout and are located near the paleo-flood tidal delta, and thus these profiles reflected a strong influence of the barrier island washover events. Sinepuxent loam, 1.0 to 1.5 m MSL (Si?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur on mainland coves and submerged wave-cut headlands, in the southern portion of the bay. These soils formed in lagoonal sediments. Sinepuxent soils (67%) are 232 loamy textured, and slightly fluid (n values > 0.7), with moderately low levels of organic carbon, and contain sulfidic materials. Contrasting soils (33%) are finer textured with buried organic horizons deeper than 100 cm below the soil surface located adjacent to the subaerial tidal marshes in the area. Southpoint silty clay loam, 1.0 to 1.5 m MSL (Sp?) ? This unit consists of very deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur on mainland coves and submerged wave-cut headlands in the northern half of Chincoteague Bay. These soils formed from lagoonal sediments, relict marsh sediments, and upland subaerial soils. Southpoint and similar soils are finer textured (SiL, L, SiCL, or CL), and slightly fluid (n values > 0.7), contain sulfidic materials, and have buried organic horizons within the upper 100 cm of the soil surface. The origin of these organic horizons in these profiles is former emergent wetlands, especially tidal marshes, which were later submerged as a result of sea-level rise during the Holocene. Similar soils include profiles that have organic horizons located deeper than 100 cm of the soil surface and those profiles that have greater than 40 cm of organic materials. Contrasting soils (43%) are may be finer textured throughout the profile and do not contain buried organic horizons, loamy texture throughout the profile, coarse textured throughout the profile or coarse textured soils that contained redoximorphic features within the upper 100 cm of the soil surface. Tingles silty clay loam, 1.0 to 1.5 m MSL (Tg?) ? This unit consists of very deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur on the lagoon bottom and thus formed in lagoonal sediments. Tingles and similar soils (80%) are finer textured (SiCL or CL), and 233 moderately fluid (n values >1), with high organic carbon contents and contained sulfidic materials within the soil profile. Contrasting soils (20%) are loamy, but are coarser textured. Tingles silty clay loam, 2.0 to 2.5 m MSL (Tg?) ? This unit consists of very deep, very poorly drained soils that are permanently submerged below 2.0 to 2.5 m of water (MSL). These soils occur on the lagoon bottom and formed in lagoonal sediments. Tingles and similar soils are finer textured (SiCL or CL), and moderately fluid (n values >1), with high organic carbon contents and contain sulfidic materials. Contrasting soils (22%) are fine textured and have buried organic horizons deeper than 100 cm below the soil surface and are located on the mainland side of the lagoon bottom, soils that contain sulfidic materials deeper in the soil profile, or soils that are loamy textured. Thorofare sandy loam, 1.0 to 1.5 m MSL (Th?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 1.0 to 1.5 m of water (MSL). These soils occur on the storm-surge washover fan slope and formed from mixed lagoon and barrier island dune sediments. Thorofare and similar soils are sandy (sandy loams, loamy sands, and sand), and non-fluid (n values <0.7) with moderately low organic carbon contents, and contain sulfidic materials. Contrasting soils (10%) are finer textured and are located near the barrier cove landform. Truitt silty clay loam, 0.2 to 1.0 m MSL (Tr?) ? This unit consists of deep, very poorly drained soils that are permanently submerged below 0.2 to 1.0 m of water (MSL). These soils occur on the mainland coves and submerged wave-cut headlands in the Johnson Bay area. These soils formed from lagoonal sediments overlying buried organic horizons that formed at or near sea level when it was at a lower elevation. Truitt and 234 similar soils (25%) are finer textured (SiCL or CL) and contain buried organic horizons deeper than 100 cm below the soil surface, are slightly fluid (n values >0.7) with moderately high organic carbon contents and contain sulfidic materials. Contrasting soils (75%) are finer textured and do not contain buried organic horizons, finer textured (SiCL or CL) over coarser textured soil (SL or LS), or loamy textured. Discussion In this study, one of our research objectives was to test the existing subaqueous soil-landscape models from other regions and determine their applicability in Chincoteague Bay. Soils occurring in the shallow, high-energy storm-surge washover fan flats were similar to those found in Ninigret Pond, RI. The soils were sandy (LfS, fS, S, or fSL), low n value, and contained sulfidic materials within the profile (Figure 5-11). However, in adjacent Sinepuxent Bay, MD, the soils on the same landforms were sandy, but sulfidic materials were not described in these profiles. Demas and Rabenhorst (1999) measured the percent chromium reducible sulfide for these soils and found it to be less than 0.1% and thus concluded that sulfidic materials were not present. They did not however, conduct moist incubations to see if the pH would drop as is required in Soil Taxonomy. Had this been done it is likely that the pH of these soils would have dropped below a pH 4, even though the sulfide minerals were present in low quantities because of the low buffering capacity and lack of carbonates. Therefore, sulfidic materials should have been described in these pedons and these soils would then be similar to those we described in adjacent Chincoteague Bay. 235 The soils occurring on the strongly sloping storm-surge washover fan slope were sandy (LfS, fS, S, or fSL), had low n values, and contained sulfidic materials within the profile (Figure 5-10). In Ninigret Pond, RI, the soils on the storm-surge washover fan slopes were very similar to those in Chincoteague Bay, but the pedons in Ninigret Pond contained buried A horizons and had an irregular C distribution with depth. In adjacent Sinepuxent Bay, MD, the most similar environment and landform was what Demas described as transitional zones. Although these soils were sandy throughout, they did not describe sulfidic materials within the pedons, perhaps for the same reasons sulfide materials were not described in the storm-surge washover fan flats. The soils occurring on the deeper, low-energy lagoon bottom, were much like those described by Demas in adjacent Sinepuxent Bay, being finer textured (SiL, SiCL), high n value, and containing sulfidic materials within the profile (Figure 5-11). We noticed that some of the upper horizons in some soils on the barrier island side of the lagoon bottom in Chincoteague Bay were coarser textured and had lower n values where they appeared to have been influenced by materials from the barrier island (Figure 5-11). This had not been recognized in previous studies, although some of the areas Demas (1998) referred to as the transition zones of Sinepuxent Bay, MD, did contain similar soils with sandy over finer textured lagoon bottom sediments. In Taunton Bay, ME the fluvial marine bottom is located in the central portion of the bay and is most similar to what we described as a lagoon bottom. Soils on this landform were also finer textured and contained sulfidic materials making them much like the soils of the lagoon bottom in Chincoteague Bay. In Taunton Bay the fluvial marine bottom is adjacent to the channel shoulder landform. Soils on this landform were also finer textured, but the presence of 236 Figure 5-10. Pedons composed of sandy materials and the corresponding map units. 237 Figure 5-11. Pedons composed of silty textures throughout (SiCL, SiL, or CL), pedons with coarser textured materials in the substratum, and pedons with a sandy surface horizons and the corresponding map units. 238 sulfidic materials was not consistent throughout the landform. They reported that areas of soil that had a vegetative cover of eelgrass (densities >50%) did not contain sulfidic materials, whereas areas with little (< 50%) or no eelgrass cover did contain sulfidic materials in the profile. In Ninigret Pond, RI, the soils of the lagoon bottom were similar to the channel shoulder soils described in Taunton Bay, ME, being fine textured, covered by eelgrass beds, and absent of sulfidic materials. It has been suggested by Osher and Flannagan (2007) that the presence or absence of vegetative cover controls the sulfur chemistry in these soils. Both the lagoon bottom of Ninigret Pond, RI, and channel shoulder of Taunton Bay, ME, are low-energy environments that should possess that ideal set of combination of properties to facilitate sulfide mineral formation, namely an anaerobic environment, a source of sulfate, fresh organic matter in the form of eelgrass detritus, an iron source (as iron oxides sorbed to fine textured mineral sediments), and sulfate reducing bacteria (Pons et al., 1982). An eelgrass vegetative cover on these soils does not seem to adequately explain the absence of sulfide bearing minerals in these environments. Eelgrass rhizomes have the ability to transport oxygen into the rhizosphere, which may oxidize sulfides to sulfates, but the rhizomes usually occur only in the upper 2 to 3 cm of the soil profile (Hansen and Lomstein, 1999). It is difficult to imagine how the oxygen transported by rhizomes could have any long term affect on soil materials deeper in the profile. Thus, this does not seem adequate to account for the lack of sulfides deeper in the soil profile. Bradley and Stolt (2001) documented sulfidic materials based on moist incubation pH data. They observed that after 120 days all of the samples showed a decline in pH (38 samples), but only one sample dropped below pH 4. These soils may have a higher buffering capacity than the 239 sandy soils which could delay the pH drop, however, these soils contained small but measurable levels of CaCO 3 (1 to 20 g kg -1 ), which was needed to keep the pH values remained around 7. It is possible that had the incubations continued for a longer period, the pH of some of these samples might have dropped below 4. Osher and Flannagan (2007) collected acid volatile sulfide data (using the method described by Cline (1969) and Ulrich et al. (1997)) in horizons to a depth of 35 cm and their data indicates the presence of monosulfides in the upper horizons (to a depth of 50 cm), but they did not indicate whether pedons were vegetated. The soils in Chincoteague Bay that were adjacent to the mainland were described in mainland cove and submerged headland landscape units and were placed into three different map units, but they generally bore certain similarities. In particular, they were finer textured (SiL, L, CL, or SiCL), contained sulfidic materials, and possessed buried organic horizons within the soil profile. The presence of the buried organic horizons was captured in the Southpoint, Truitt, and Tumagan series concepts, all of which contain buried organic horizons within the profile (Figure 5-12). The Southpoint soils have buried organic horizons within 100 cm of the soil surface that are at least 20 cm thick, whereas, the Truitt soils have a buried organic horizon occurring deeper than a meter and which must be at least 5 cm thick. Tumagan soils are Histosols and thus have organic horizons that comprise at least 40 of the upper 80 cm of the soil. We observed that the organic horizons often tend to become thinner and denser the deeper they are found in the profile. This phenomenon may be due to decomposition or the compaction caused by the weight of the overlying horizons and water. These buried organic horizons are located at the shallowest depths closest to the mainland shore and are found deeper in the soil 240 Figure 5-12. Location of pedons in Chincoteague Bay that were shallow organic soils (Histosols, Tumagan series), or that contained organic horizons within 100 cm of the soil surface (Thapto-Histic, Southpoint series), or organic horizons deeper than 100 cm (Typic, Truitt series). 241 profile with increasing distance from the shoreline, extending into the lagoon bottom landform. The depth of the buried organic horizon and the distance below MSL were used in conjunction with the 14 C dates to determine when these horizons were at sea level. The dates indicate that buried organic horizons closest to the current shoreline are the youngest, whereas the horizons farthest from the shoreline were the oldest. Therefore, I believe these horizons represent intact portions of a larger tidal marsh system that became submerged overtime due to sea level rise, rather than organic fragments collecting in these low-energy environments due to wave erosion of adjacent tidal marsh areas. In adjacent Sinepuxent Bay, MD, deep mainland coves contained soils similar to those described on the mainland cove and submerged headland landscape units. Soils on the deep mainland coves were fine textured (SiL or SiCL), contained sulfidic materials, and buried organic horizons within the upper 100 cm of the soil surface. However, in Ninigret Pond, RI, mainland cove soils were loamy textured (SiL, fSL, or LS) and contained organic horizons within the upper 100 cm of the soil surface, but apparently did not contain sulfidic materials (identified using moist incubations). Osher and Flannagan (2007) described soils on the terrestrial edge located in the intertidal regions that were most similar to what we described on the mainland side of the lagoon bottom. Soils in the submerged marsh unit located on the terrestrial edge are fine textured (SiCL), contain sulfidic materials, and have buried organic horizons located deeper than 100 cm below the soil surface. The soils occurring in the low-energy barrier coves were finer textured in the upper horizons overlying coarser materials at depth and contained sulfidic materials within the profile. In adjacent Sinepuxent Bay, MD, the most similar environments and 242 landforms are what Demas (1998) described as the barrier island flats. These soils were coarse textured with an irregular organic C distribution and had sulfidic materials within the profile. Bradley and Stolt (2003) described soils located in the barrier coves which were similar to those we described in Chincoteague Bay, being finer textured overlying sand or gravel with sulfidic materials within the upper profile. The soils occurring on dredged shoals were sandy and contained sulfidic materials in the profile. In adjacent Sinepuxent Bay, Demas described soils on a mid-bay shoal that were loamy, but coarser textured with sulfidic materials in the profile. These soils also contained buried A horizons that probably represented the original surface before the dredging activities. Bradley and Stolt (2003) described soils on shoals (island remnants) being sandy textured; however, these soils did not contain sulfidic materials as we found in Chincoteague Bay. In Taunton Bay, ME, the shoals that were described were not the result of dredging or eroded islands, but were created from the biological activity of mussels. The soils were different from those we described in Chincoteague Bay being that they were silty textured (less than 8% clay), had very shelly surface horizons (containing greater than 60% shells), but nevertheless contained horizons within the upper portion of the profile that met the qualifications for sulfidic materials (Osher and Flannagan, 2007). The soils occurring in the fluviomarine bottom in Chincoteague Bay were much like those first described by Coppock et al. (2004) in Rehoboth Bay, DE. These soils formed in areas where fresh water inputs collided with brackish water, which caused flocculation of the suspended fraction (Aston, 1980). This process of flocculation and settling created soils that were finer textured, very fluid (n values > or >>1), and 243 contained sulfidic materials within the profile. Nothing comparable to this landform was described other than Coppock et al. (2004). The soils occurring on the shallow, high-energy paleo-flood tidal delta were unique to Chincoteague Bay. This study was the first to document soils occurring on the paleo-flood tidal delta landforms, although several studies have described the soils located on active flood-tidal delta flats (Bradley and Stolt, 2003; Coppock et al., 2004). The soils were sandy and contained sulfidic materials within the profile. In contrast, soils located on active flood-tidal delta flats are young, sandy soils that do not contain sulfidic materials due to the constant influx of oxygenated waters through the inlet and the instability of the soils and landforms themselves (Bradley and Stolt, 2003). Once the inlet closed, the flood-tidal delta flats age and sulfides begun to accumulate in the soils, due to the lack of oxygenated waters flushing through the sediments and greater stability of the landforms due to weaker currents. The conceptual models developed in previous studies to describe the soil- landscape relations on mainland coves, barrier coves, storm-surge washover fan flats, and fluviomarine bottoms were useful in Chincoteague Bay in describing the distribution of subaqueous soils in Chincoteague Bay. The subaqueous soil-landscape model developed for the lagoon bottom by Demas (1998) was accurate so far as it went in describing the subaqueous soils of Chincoteague Bay, but was poorly documented with only a single pedon description but with no accompanying lab data. The work in Chincoteague Bay has enhanced this model making it more robust by adding a significant body of characterization data on these soils. We revised the model to better accommodate soils on the barrier island side of the lagoon bottom that are influenced by barrier island overwash 244 during very strong storm events. The concepts developed by Demas (1998) for the transitional areas and by Bradley and Stolt (2003) for the storm-surge washover fan slopes did not accommodate the soils of Chincoteague Bay very well. Therefore we modified the model to reflect the presence of sulfidic materials. The model developed for shoals in previous studies has limitations in describing the soils located on shoals in Chincoteague Bay. Due to the nature of the shoals (or how they were created) it may not be possible to develop a more general model that will be accommodating for all coastal lagoons or estuaries. In Ninigret Pond, RI, the shoals were island remnants. The islands were eroded by waves and submerged by sea level rise. The soils located on these shoals are composed of primarily of upland soils rather than estuarine materials. In contrast, the shoals in Taunton Bay, ME, formed as a result of mussels growing on the fluvial marine terrace landscape surfaces. The soils of paleo-flood tidal delta landforms had not been previously described. Therefore, this was a new addition to concepts describing soil- landscape relationships on the barrier side of the coastal lagoon. The soils of submerged wave-cut headlands landform had not been previously described in other studies. These landforms are found adjacent to promontory areas located along the Chincoteague Bay coast and formed as a result of erosion and submergence due to sea level rise. The soils on these landforms were similar to those described in the adjacent mainland cove landscape units. Therefore, the model developed for the mainland coves accurately described the majority of the soils located on these landforms. Conclusions Several of the subaqueous-soil landscape models previously developed in other coastal lagoons and estuaries were substantially applicable in the large coastal lagoon, 245 Chincoteague Bay. However, the subaqueous soil-landscape models developed for the lagoon bottom, storm-surge washover fan slopes, and shoals had limitations and needed to be enhanced to accommodate the soils described in Chincoteague Bay. We added to the existing models to include two additional subaqueous landforms that were not identified in previous studies. These were the paleo-flood tidal delta and submerged wave-cut headlands. Based on the subaqueous soil-landscape models, 13 subaqueous soil map units were identified in the construction of a soil map of Chincoteague Bay, Maryland, providing the first soil resource inventory for the largest of Maryland?s coastal bays. 246 Chapter 6: Utilization of Subaqueous Soils Information for Assessing Submerged Aquatic Vegetation Habitat Introduction Submerged aquatic vegetation (SAV) performs a variety of important ecosystem services. They function as feeding sites for waterfowl, nurseries, and cover areas for juvenile shellfish and finfish. Their leaves provide a substrate for the attachment of eggs and organisms such as barnacles and polychaetes. Submerged aquatic vegetation also modifies soil geochemistry through photosynthesis, by releasing oxygen into the soil and through the cycling and uptake of nutrients (Batiuk et al., 2000). The health and abundance of plants that live in bay soils often are used as indicators of estuarine health (Stevenson et al., 1979; Wazniak and Hall, 2005), as plants require relatively clear water for photosynthesis. In the 1970s decline of SAV beds in the Chesapeake Bay was documented, and the potential causes for that decline included disease, nutrient enrichment, high levels of suspended solids, low levels of dissolved oxygen, toxic contaminants, and decreased light availability. Following the loss of SAV beds, declines in waterfowl, rockfish, oyster, and crab populations were observed (Chesapeake Bay Program, 1991). Thus, research efforts were directed towards identifying the causes of SAV decline, and the Chesapeake Bay Program (1992) published a report concluding poor water quality was responsible. Water Quality Parameters Seagrass populations have been studied since the 1930s when the seagrass Zostera marina experienced a dramatic decline along the Atlantic coast (Short, 1987). 247 These studies have attempted to identify the environmental factors that influence seagrass populations. The primary cause for the loss of SAV in many estuaries and coastal lagoons has been related to the reduction in light availability (Kemp et al., 2004). Reductions in light availability have been linked to increased nutrient inputs, chlorophyll-a, and suspended sediments (Kemp et al., 1983; Batiuk, 1992). The processes responsible for the attenuation of light in estuaries that reduces its availability to SAV are shown in Figure 6-1. Dissolved inorganic nutrients (nitrogen and phosphorus) in the water column increase the growth of phytoplankton and algae which decreases the amount of light that reaches the SAV (Batiuk et al., 2000). The water quality parameters established for the Chesapeake Bay are presented in Table 6-1. As expressed in these factors, Kemp et al., (2004) estimated the minimum light for SAV survival required at the canopy height (percent light through water (PLW)) to be 22% and at the leaf surface (percent light at the leaf (PLL)) to be 15 to 9% for the polyhaline regions of Chesapeake Bay. Tides and waves change the water column height and increase the suspended solids through the resuspension of bottom sediments, which changes the light attenuation in the water column (Koch, 2001). Several other factors have been implicated as factors controlling seagrass populations including water depth, availability of nutrients, toxic material, and sediment conditions (Short, 1987). However, the factors that affect the success and survival of seagrasses often are overlapping and it becomes difficult to evaluate these factors independently. The range in suitable water depths has largely been attributed to differences in light attenuation. The maximum depth of seagrass occurrence in these coastal waters is often determined based on maximum light attenuation in clear water, but 248 Figure 6-1. A conceptual model showing how the attenuation of light as it passes through the estuarine water column that reduces its availability for SAV to support photosynthesis (modified by Batiuk et al., 2000). 249 Table 6-1. Habitat recommendations for submerged aquatic vegetation growth and survival in the polyhaline portion of Chesapeake Bay developed by the Chesapeake Bay Program (modified from Batiuk, 2000). Component Habitat Requirements Minimum Light Requirement > 15% Water Column Light Requirement > 22% Total Suspended Solids < 15 mg l -1 Plankton Chlorophyll-a < 15 ?g l -1 Dissolved Inorganic Nitrogen <0.15 mg l -1 Dissolved Inorganic Phosphorus <0.01 mg l -1 250 microalgal blooms and turbidity will limit the depth that seagrasses will survive. Water depth also impacts the grain size composition of the sediments. In shallow, high-energy environments the sediments are often coarse textured and contain little to no fine materials and organic matter compared to deeper, low-energy settings that contain finer textured sediments high in organic matter. Therefore, the water depth influences the maximum depth seagrasses would grow, but is also dependent on the water quality parameters including chlorophyll-a and total suspended solids and the sediment composition. Soil Parameters In addition to water quality parameters several studies have begun to recognize soil characteristics as another important factor affecting seagrass distribution. Soils can impact the growth, morphology, and distribution of seagrasses due to erosional/ depositional processes, availability of nutrients, and presence or absence of phytotoxins. Several soil characteristics have been shown to impact the growth and success of SAV including high porewater sulfide concentration, high organic matter content, and grain size distribution. These factors are often correlated. An overview of these studies is presented in Table 6-2. Hydrogen sulfide is a known phytotoxin to wetland macrophytes including Spartina alterniflora, Spartina townsendii, Panicum hemitomon, and rice plants (Koch and Mendelssohn, 1989; Goodman and Williams, 1961; Okajima and Takagi, 1953). In hydroponic experiments, Goodman and Williams (1961) demonstrated that the addition of 0.94 mM H 2 S caused Spartina townsendii rhizomes to become ?soft rotted? and in similar studies, Koch and Mendelssohn (1989) demonstrated that the addition of 1.0 mM 251 Table 6-2. Summary of soil/sediment characteristics defining habitat constraints for submerged aquatic vegetation in fresh water and marine environments. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Sulfide concentrations Zostera marina Polyhaline 200 to >800 ?M <200 ?M >400 ?M Laboratory experiment in Chincoteague Bay, MD using mesocosms collected from Chincoteague Bay sediments and to treated to reduce or increase ambient sulfide levels to study the impact on photosynthesis Goodman et al 1995 <6.5 ?M in porewater unvegetated sites 1.1 to 43 ?M in porewater vegetated sites AVS and CRS 0.6 to 3.2?M cm -3 (0.02 to 0.5 g kg -1 ) Field study in Roskilde Fjord, Denmark measuring biomass and sediment sampling. Holmer and Nielsen 1997 72.7 ?M Field study Roskilde Fjord, Denmark examining the effect of the addition of sucrose on sediment conditions. Terrados et al. 1999 < 5 g kg -1 Chromium reducible sulfides Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 252 Table 6-2. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Sulfide Concentrations Zostera marina Polyhaline 0.3 to 1.5 g kg -1 Acid volatile sulfides Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 <100 ?M >400 ?M Compilation of data from literature, suggested values only. Koch 2001 Ruppia maritima < 5 g kg -1 Chromium reducible sulfides Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Seagrasses >200 ?M Review of literature. Kemp et al. 2004 Organic Matter Zostera marina 0.4 to 0.5 % organic matter Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 0.8 to 1.4 % organic matter Field study in Chesapeake Bay measuring biomass and sediment sampling. Orth 1977 0.9 to 3.4 % organic carbon <2 % organic carbon >3 % organic carbon Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 0.2 to 7 % organic carbon Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 <4 % organic carbon Observations made in Taunton Bay, ME during soil sampling. Osher and Flannagan 2007 253 Table 6-2. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Organic Matter Ruppia maritima Polyhaline 0.9 to 3.4 % organic carbon <2 % organic carbon >3 % organic carbon Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Ruppia maritima Mesohaline <2 % organic matter Field study in Chesapeake Bay examining suspended particulate material in vegetated areas. Ward et al. 1984 Halodule wrightii Polyhaline 0.4 to 0.5 % organic matter Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 Seagrasses Fresh water to polyhaline 0.8 to 16.4 % organic matter <5 % organic matter 6.5 to 16.4 % organic matter Compilation of data from literature, suggested values only. Koch 2001 <5 % organic matter >5 % Review of literature. Kemp et al. 2004 Grain Size Zostera marina Polyhaline Sandy substrates Observational study in Chesapeake Bay, MD. Hurley 1990 Sand to sandy loam Loamy sand Silt loam Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Coarse sand to silt loam Very fine sandy loam to silt loam Coarse sand to very fine sand Field study in Ninigret Pond, RI measuring biomass and soil types. Bradley and Stolt 2006 5 to 11 % silt and clay Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 85 to 92% sand Field study in Chesapeake Bay measuring biomass and sediment sampling. Orth 1977 254 Table 6-2. Continued. Sediment Characteristics Seagrass Type Ecological Environment Range where growing Optimum Range Limiting Range Type of Research Reference Grain Size Zostera marina Polyhaline Silt loam Observations made in Taunton Bay, ME during soil sampling. Osher and Flannagan 2007 Cobble free and < 70% silt/clay Site selection model, Preliminary Transplant Suitability Index (PTSI) for identification of potential Zostera marina habitat in New Hampshire. Short et al 2002 Ruppia maritima Silt/clay mixture to coarse sand Fine to medium sand Experimental using grain sizes of ground glass. Seeliger and Koch (unpublished) Sand to sandy loam Loamy sand Silt loam Dense sands Field study in Sinepuxent Bay, MD measuring biomass and soil types. Demas 1998 Halodule wrightii 5 to 11 % silt and clay Field study in North Carolina measuring biomass and sediment sampling. Fonseca and Bell 1998 Seagrasses Marine/ estuarine 0.4 to 72% silt and clay (<63 ?m) <20% silt and clay Compilation of data from literature, suggested values only. Koch 2001 0.4 to 72% silt and clay (<63 ?m) <20 to 30% silt and clay (by weight) Review of literature. Kemp et al. 2004 255 H 2 S resulted in lower biomass of marsh grass species Spartina alterniflora and Panicum hemitomon. Okajima and Takagi (1953) showed limited rice aboveground growth and root hair development in the presence of 1.0 mM H 2 S. It has also been demonstrated that porewater sulfide is toxic to estuarine and marine SAV species. Elevated porewater sulfide levels may contribute to seagrass die-off in areas with extra stresses such as decreased light availability due to water column turbidity or shading by macroalgae or epiphytes (Lee and Dunton, 2000). Goodman et al. (1985) demonstrated that mesocosm sediments with sulfide concentrations between 100 and 200 ?M had a negative impact on photosynthesis in Zostera marina. Measurements of porewater sulfides in estuarine systems were more difficult to obtain due to the ephemeral and transitory nature of soluble sulfide in these environments (Carlson et al., 1994). Sediment sulfide concentrations, as sulfide bearing minerals, can be used as a surrogate in estimating the concentration of soluble sulfide in estuarine/marine environments. It can be reasoned that sediments with higher soluble sulfide generation have an increased likelihood for sediment sulfide accumulation as monosulfides and disulfides. The concentration of solid phase sulfides in these sediments is less ephemeral and easily obtainable in these environments. Thus these data could be used to indicate the potential for sulfide toxicity. In Sinepuxent Bay, MD, where sediment sulfide concentrations were measured in areas with healthy Zostera marina and Ruppia martima beds the levels were less than 5 g kg -1 (Demas and Rabenhorst, 1999). These values were greater than concentrations measured by Bradley and Stolt (2006) in sediments supporting healthy Zostera marina where concentrations were less than 1.5 g kg -1 and in Demark sediments supporting Zostera marina had values less than 0.5 g kg -1 (Holmer and Nielsen, 1997). Although the studies 256 examining the relationship between sediment sulfide concentrations and SAV growth are limited, we can reasonably surmise that low sediment sulfide concentrations are favorable for healthy SAV habitats. Organic matter in submerged sediments has been shown to have a positive effect on plant growth, due to the release of nitrogen and phosphorus during the mineralization of the organic matter (Sand-Jensen and Sondergaard, 1979). However, at high quantities organic matter has a negative effect on the growth of submerged macrophytes probably due to their contribution to the formation of phytotoxins, such as S 2- in anoxic sediments (Barko and Smart, 1983). In the Mid-Atlantic region healthy Zostera marina has been observed growing on sediments with organic matter contents less than 2% (Orth, 1977; Ward et al., 1984; Demas, 1998). However in Rhode Island, Bradley and Stolt (2006) found Zostera marina growing on soils with higher organic matter contents (up to 4%) than in the Mid-Atlantic region. The limitation of higher organic matter content on SAV growth is not well understood (Koch, 2001) although it may be related to nutrient limitation in very fine sediments associated with high organic deposits (Barko and Smart, 1986) or to high sulfide concentrations associated with increased reduction of sulfate and organic matter oxidation (Nienhus, 1983; Goodman et al., 2005). Overall the organic matter content of sediments supporting healthy Zostera marina and Ruppia martima was generally less than 5% (3% organic carbon) (Table 6-2). Submerged aquatic vegetation growth is also impacted by physical and geochemical processes that are associated with grain size distribution (Barko and Smart, 1986). In experiments using glass beads, Seeliger and Koch (unpublished) found that Ruppia maritima had maximum growth in fine to medium sand-sized particles. Demas 257 (1998) observed Zostera marina and Ruppia martima growing on loamy sand (<15 % silt and clay) soils in Sinepuxent Bay, MD, which was similar to observations made by Orth (1977) in the Chesapeake Bay where Zostera marina was growing on sediments with 85 to 92% sand. Hurley (1990) also made observations in regard to the type of sediments inhabited by several SAV species in Chesapeake Bay, including Zostera marina which grew primarily on sandy substrates and Ruppia maritima that was occasionally found on soft muddy sediments but was more commonly on sandy substrates. In contrast to these Mid-Atlantic based studies, Bradley and Stolt (2006) observed Zostera marina growing on soils in Ninigret Pond, RI, with greater quantities of silt (>21%) and clay (>8). Observations collected by Osher and Flannagan (2007) in Taunton Bay, ME, also described Zostera marina growing on finer textured (silt loam) soils. According to a review of Kemp et al. (2004), Zostera marina and Ruppia maritima are generally more abundant in sediments in which silts and clays constitute less than 20 to 30% (by weight). However, several studies indicated that healthy Zostera marina beds were located on sediments with higher amounts of silt and clay. Short et al. (2002) developed a three phase site selection model for Zostera marina transplant projects. In this model a general rule was derived from the literature indicating that the preferred sites have sediment conditions that were cobble free and contained less than 70% silt and clay. Grain size distribution impacts the rate of porewater exchange in the sediments and the amount of nutrients in the sediments. Grain size distributions that are skewed towards silt/clay have lower porewater exchange rates with the overlying water column than sandier sediments (Huettel and Gust, 1992), which can lead to increased nutrient levels but also higher sulfide concentrations in the sediments and porewater (Kenworthy 258 et al., 1982; Holmer and Nielsen, 1997). In higher salinity (18 to 30 ppt) environments it seems as though SAV prefer to inhabit more oxygenated coarser textured sediments (Koch, 2001) that permits higher porewater exchange with the overlying water, which helps maintain tolerable sulfide concentrations in these soils. The sediment factors impacting SAV growth and distribution in estuarine and marine environments are not completely independent factors as presented. As wave and current energies decrease, finer sediments and organic matter collect in these low energy environments. These low- energy environments are also conducive for sediment sulfide generation. Thus, the areas with finer textured sediments tend to have higher organic matter and sediment sulfide contents compared to the high-energy environments. The seagrasses reproduction and recruitment also plays a role in the location and distribution in estuarine environments. Orth et al. (1994) broadcast Zostera marina seeds into three unvegetated plots in the Chesapeake Bay (York River, VA) which historically supported vegetation. The seedlings were distributed within 5 m plots, but not beyond these areas. They suggested that the seeds were protected from current flows by microtopographic features (burrows, pits, mounds, and ripples) and demonstrated that seeds settled rapidly and became incorporated into the sediments. These results suggest that seeds stay locally where they were distributed and do not tend to have large scale distribution patterns. Thus, the seed distribution should be taken into consideration in restoration of large landscapes. Due to this overlapping influence of variables within the water column and the sediment it is particularly hard to evaluate suitable habitats for SAV growth and success. But in this chapter we will be focusing on the properties of the soils that impact SAV 259 knowing that the surrounding environmental conditions are also impacting their growth and success. Uses of Soil Inventory Data Soil inventory data are commonly used to provide information regarding the suitability or limitations of the soils for specific land uses. This involves evaluating soil attributes that impact a specific land use in order to make predictions about how a soil will behave or about how the soil properties will affect certain land uses. This information is usually expressed in suitability maps or tables highlighting the severity of the limitations and the limiting soil properties for specific land uses. These suitability maps and tables are often used to assist in management decisions. For example, soil inventory data commonly are used to generate potential agricultural yields, to assess suitability for septic leaching fields, or to predict usefulness for wetland wildlife habitat. In each of these examples, factors other than soils also impact the success or viability of particular land uses, but the limitations offered by the soils themselves can nevertheless be evaluated independently. In a similar fashion, the subaqueous soils information obtained for Chincoteague Bay can potentially be used to help identify which areas are well suited or poorly suited for SAV habitat based on the physical and chemical properties of the soils. The suitability of the subaqueous soils for potential SAV habitat restoration, for example, could then be displayed in tabular or graphical form. The objectives of this study were 1) to compare published data on soil properties affecting SAV growth to the properties of the soils of Chincoteague Bay; 2) using information obtained in objective 1, create a suitability map for SAV growth based on the 260 soil properties of Chincoteague Bay; and 3) to evaluate the usefulness of the suitability map by comparing it with SAV distributions documented in Chincoteague Bay. Material and Methods Study Site Chincoteague Bay is the largest coastal lagoon (19,000 ha in Maryland) on Maryland?s eastern shore with inlets located at Ocean City, MD and Chincoteague, VA. It is a shallow (<3 m), microtidal lagoon with salinity values ranging from 26 to 34 ppt. Wazniak and Hall (2005) summarized overall ecological conditions of the Maryland coastal bays by using the estuarine health indicators comprised of water quality (water quality index, brown tides, and macroalgae), living resource indicators (benthic index, hard clam abundance, sediment toxicity), and habitat indicators (seagrass area, wetland area, natural shoreline). According to this report, the northern most bays (Assawoman Bay, Isle of Wight Bay, and Newport Bay) have the poorest estuarine health, whereas the health of Sinepuxent Bay and Chincoteague Bay is better. The good condition of Chincoteague Bay is due primarily to the relatively undeveloped watershed, low sediment toxicity values, and presence of seagrass beds. However the presence of brown tides and macroalgal blooms reduced its overall ranking to second (behind Sinepuxent Bay). Soils of Chincoteague Bay One-hundred and forty-six pedons from Chincoteague Bay were examined and described according to the National Soil Survey Center guidelines (Schoeneberger et al., 2002). Samples from 51 of the pedons were analyzed for selected properties. Methods of 261 handling and analyses of the samples were presented in Chapter 4. After characterization, the soils were classified to the series level according to the Keys to Soil Taxonomy (Soil Survey Staff, 2006) and proposed amendments to Soil Taxonomy (Northeast Regional Cooperative Soil Survey Subaqueous Soils Committee, 2007). The classification of these soils is presented in Chapter 4. Using the soil-landscape models developed for Chincoteague Bay, a soil resource map was developed and is presented in Chapter 5. The soil map and accompanying characterization data set were compared with published information from the literature to determine optimum soil characteristics for SAV growth. The high resolution orthomosaic photograph used in Figures 6-2, 6-4, 6-5, 6-6, and 6-10 was provided by USDA-NRCS Geospatial Data Branch in Fort Worth, TX (USDA-NRCS, 2001). Submerged Aquatic Vegetation Information for Chincoteague Bay Submerged aquatic vegetation coverage was obtained from the Virginia Institute of Marine Science (VIMS). The Virginia Institute of Marine Science has been collecting SAV coverage data for the Chesapeake Bay and the Maryland coastal bays since 1986. The available SAV coverage was mapped from 1:24,000 black and white aerial photographs obtained during the peak growing season of the species known to occur in the area (Orth et al., 2005). In Chincoteague Bay Zostera marina (eelgrass) has a growing season from March through May and October through November and Ruppia maritima (widgeon grass) has a growing season from April through October. Using rectified photography, the distribution of SAV was mapped and density was determined using a crown density scale developed for establishing crown cover of forest trees (Orth et al., 262 2005). For quality assurance purposes the SAV beds identified by aerial photo interpretation were also field checked by VIMS staff and collaborators. Analysis Using soil characteristics that impact the growth of SAV a soil suitability map for potential SAV habitats was created using ArcMap 9.0 (ESRI Inc., 2006). The 2004 SAV coverage map was used to evaluate the usefulness of the soil suitability map by determining the SAV coverage and density within each soil map unit using ArcMap 9.2 (ESRI Inc., 2006). During the process of describing soils at 146 locations in Chincoteague Bay we noted the presence of SAV growing on these soils or evidence of roots within the surface horizons if the vegetation was absent. The location of the pedons with and without evidence of SAV was compared with the soil map using ArcMap 9.0 (ESRI Inc., 2006). Results Based on the data collected from the literature presented in Table 6-2, we summarized the soil characteristics that impact SAV growth and success. A summary of pertinent soil characteristics and the ranges associated with the suitability classes are presented in Table 6-3. Porewater sulfide concentrations were not measured in these soils. However, it has been suggested that soil sulfide concentrations can be used as a surrogate for porewater sulfide concentrations. Soils with low sulfide contents and low organic carbon contents would have low porewater sulfide levels since organic matter would tend to limit sulfate reduction in these soils. Thus, the soil sulfide concentrations 263 should be positively related to porewater sulfide concentrations in these environments. Therefore, we are using soil sulfide concentrations as a property to indicate porewater sulfide toxicity on SAV growth. The organic carbon content in these soils for favorable conditions was based on studies indicating that SAV was found on soils with less than 5% organic matter (3% organic carbon) (Koch, 2001; Kemp et al., 2004). The soils with mildly detrimental levels of organic carbon were based on the upper limit where healthy SAV was found growing (Bradley and Stolt, 2006). In the Mid-Atlantic region, SAV was found on sandier soils than farther to the Northeast where SAV was found growing on loamy textured soils. Therefore, the favorable textures reflect the Mid-Atlantic region and the mildly detrimental textures reflected the loamier textures found in the Northeast. These characteristics were then used to determine the overall rating of the soils in Chincoteague Bay. The favorable and potentially limiting soil characteristics that impact SAV growth in Chincoteague Bay and the overall rating of the soils are presented in Table 6-4. Based on these soil characteristics we predicted the suitability of the soils in Chincoteague Bay for potential SAV habitats as slight, moderate, or severe. The predicted soil suitability map is shown in Figure 6-2. The soils in Chincoteague Bay that have slight limitations for SAV growth had sandy surface textures (fs or lfs), low and moderately low organic carbon contents (<2.7 g kg -1 ), and low sulfide levels (<0.07 g kg - 1 ). The soils with moderate limitations for SAV growth had sandy to loamy surface textures (cS, fS, LfS, SL, fSL, L, SiL, or SiCL), moderately low to high organic carbon contents (2 to 57 g kg -1 ), and intermediate sulfide levels (1.5 to 11.6 g kg -1 ). The soils in Chincoteague Bay with severe limitations for SAV growth had finer surface textures (L, 264 Table 6-3. Summary of soil properties based on a literature review of Zostera marina (eelgrass) and Ruppia maritima (widgeon grass) which were used to determine the suitability of the soils in Chincoteague Bay. Soil Property Favorable Mildly Detrimental Strongly Detrimental Sulfide concentration <5 g kg -1 >5 g kg -1 Organic carbon content < 30 g kg -1 30-70 g kg -1 >70 g kg -1 Texture <20% silt and clay (by weight) S or LS 20 to 50% silt and clay (by weight) SL, SCL, or L >50% silt and clay (by weight) SiL, SiCL, CL, SiC, C 265 Table 6-4. Soil map units and favorable and limiting soil characteristics that may impact SAV growth in Chincoteague Bay. Soil Map Unit Favorable Properties Potentially Limiting Properties Overall Rating Co?: Coards silty clay loam, 1.0 to 1.5 m depth Organic carbon content 9.0- 21.0 g kg -1 high levels of sulfides, SiCL or CL textures Severe Ct?: Cottman sand, 1.5 to 2.0 m depth Organic carbon content 1.5- 4.0 g kg -1 , sandy textures Moderate levels of sulfides (1.5 to 6.5 g kg -1 ), Slight De?: Demas fine sand, 0.2 to 1.0 m depth Organic carbon content 0.4- 2.7 g kg -1 , low levels of sulfides (0.07 to 0.32 g kg - 1 ), sandy textures Slight De?: Demas fine sand, 1.0 to 1.5 m depth Organic carbon content 0.5- 3.0 g kg -1 , low levels of sulfides, sandy textures Slight Dm?: Demas sandy loam, 1.0 to 1.5 m depth Organic carbon content 2.4- 7.5 g kg -1 , low levels of sulfides, sandy textures Slight Mm?: Middlemoor sandy loam, 0.2 to 1.0 m depth Organic carbon content 24.0- 57.0 g kg -1 , moderate levels of sulfides, SL, L, or SiL surface textures Moderate Mm?: Middlemoor sandy loam, 1.0 to 1.5 m depth S surface textures, organic carbon content 2.0-14.0 g kg -1 Moderate to high levels of sulfides (1.1 to 7.6 g kg -1 ) Moderate Si?: Sinepuxent loam, 1.0 to 1.5 m depth Organic carbon content 9.6- 23.5 g kg -1 SL, L, or SiCL surface textures, moderate levels of sulfides Moderate Sp?: Southpoint silty clay loam, 1.0 to 1.5 m depth High quantities of silt and clay, organic carbon content 2.5- 202.0 g kg -1 , high levels of sulfides (16.2-19.7 g kg -1 ) Severe Tg?: Tingles silty clay loam, 1.0 to 1.5 m depth Organic carbon content 5.6- 12.0 g kg -1 High quantities of silt and clay, high levels of sulfides Severe Tg?: Tingles silty clay loam, 2.0 to 2.5 m depth Organic carbon content 5.3- 17.0 g kg -1 High quantities of silt and clay, moderate to high levels of sulfides (3.2-10.0 g kg -1 ) Severe Th?: Thorofare sandy loam, 1.0 to 1.5 m depth Sandy textures, low organic carbon (0.7-3.0 g kg -1 ) Moderate levels of sulfides Slight Tr?: Truitt silty clay loam, 0.2 to 1.0 m depth LfS or LS surface textures, Organic carbon content 9.7- 18.6 g kg -1 CL or SiCL surface textures, moderate levels of sulfides Severe 266 Figure 6-2. Predicted soil suitability for SAV habitat based on soil characteristics including sulfide concentration, texture, and organic carbon content. Soil map units were grouped based upon their degree of limitation (slight, moderate, or severe) for SAV habitat. 267 SiL, SiCL, or CL), moderately high to high organic carbon contents (5.6 to 202.0 g kg -1 ), and intermediate to high sulfide levels (3 to 66 g kg -1 ). In the 1930?s the eelgrass disappeared from Chincoteague Bay due to an eelgrass blight (discovered to be a marine pathogenic slime mold) which impacted the East Coast from North Carolina to Newfoundland (Short et al., 1993). Maryland?s coastal bays gradually recovered from the massive decline but according to Orth and Moore (1983) have not reached the historical high levels. Since 1986 the Virginia Institute of Marine Science (VIMS) has conducted annual surveys of SAV distribution in the Maryland coastal bays. Seagrass coverage has increased by an average of 301 ha per year (Figure 6- 3), however between 2004 and 2006 there was a serious decline (44%) in the seagrass coverage from 5732 ha to 3204 ha (Orth et al., 2004; Maryland Department of Natural Resources, 2007). This decline has been attributed to an increase in water temperatures in 2005 along with increasing nutrient and chlorophyll trends in the area (Maryland Department of Natural Resources, 2007). Although there has been a decline in seagrass beds since 2004, Chincoteague Bay continues to have the highest SAV coverage in the Maryland coastal bays. The SAV distribution and density collected in 1986 (this was the first data collected when the monitoring began in the coastal bays) is shown in Figure 6- 4. The most recent SAV distribution and density data available was collected in 2004 and is shown in Figure 6-5. Four density classes were identified based on the percent cover: very sparse (<10% coverage); sparse (10-40% coverage); moderate (40-70% coverage); and dense (>70% coverage). Most of the seagrass beds occur on the eastern side of 268 Figure 6-3. Annual seagrass coverage (ha) for Chincoteague Bay from 1986 through 2006. Submerged aquatic vegetation coverage was obtained from the Virginia Institute of Marine Science (VIMS). 269 Figure 6-4. The SAV distribution and density collected in 1986 by VIMS using rectified photography was obtained during peak SAV growing season. Four density classes were identified based on the percent cover: very sparse (<10% coverage); sparse (10-40% coverage); moderate (40-70% coverage); and dense (>70% coverage). 270 Figure 6-5. The SAV distribution and density collected in 2004 by VIMS using rectified photography was obtained during peak SAV growing season. Four density classes were identified based on the percent cover: very sparse (<10% coverage); sparse (10-40% coverage); moderate (40-70% coverage); and dense (>70% coverage). 271 Chincoteague Bay behind Assateague Island. However in 2004 several beds were located along the mainland in the southern portion of the bay. The 2004 VIMS data set is the most recent digital dataset available and was used in this study because the total SAV coverage has changed very little from 1998 through 2004. In order to test the usefulness of the soil rating scheme that was developed using the criterion in tables 6-3 and 6-4, the locations of actual SAV beds identified by VIMS in 2004 were compared with the suitability map using ArcGIS. The VIMS 2004 SAV coverage for Chincoteague Bay was overlain on the soil suitability map Chincoteague Bay (Figure 6-6). From this data set we calculated the area of SAV within each density class that was located within each soil suitability class using ArcGIS 9.2 (ESRI Inc., 2006). The total area of SAV for each density class within each soil suitability unit is presented in Figure 6-7. The greatest SAV coverage (approximately 3000 ha) was located on the soils identified as having a slight limitation. These soils with slight limitations contained the broadest SAV coverage in each of the SAV density classes. The soils with severe limitations had the lowest SAV coverage (140 ha) and do not contain any SAV beds with dense (70-100%) coverage. The percentage distribution of each SAV density class among the three soil suitability units is shown in Figure 6-8. By far the greatest proportion of each density coverage occurs on soils with slight limitation. With the exception of the lowest density class (<10 %), the proportion is much greater on soils described as having moderate limitation than on those with severe limitations. The percent of SAV coverage for each suitability class is shown in Figure 6-9. The soils with slight limitations had the greatest percent coverage (36 %) of the suitability classes for each density class, with exception of the >70 % class which had the greatest coverage on 272 Figure 6-6. The SAV coverage in 2004 and the potential suitability for SAV growth based on soil characteristics of Chincoteague Bay. Note that most of the SAV beds are located adjacent to the barrier island. 273 Figure 6-7. The total hectares of SAV per density class found within each soil suitability unit in Chincoteague Bay, Maryland. Note the highest SAV coverage is found within the slight class. 274 Figure 6-8. The percentage of SAV for each density class is shown for each suitability class (each density class adds up to 100%). Note the greatest SAV coverage was located on soils with slight limitations for SAV growth. 275 Figure 6-9. Percent of the total area designated within each soil suitability class in Chincoteague Bay that supported SAV growth in 2004 (by density class). Note the highest percentage (35%) by SAV occurred in areas with slight limitations with only 1% coverage in areas with severe limitations. 276 the soils with moderate limitations. The soils with severe limitation had only 1% of the total area covered by SAV. Based on this analysis SAV was most abundant on the soils with slight limitations and almost non existent on those soils with severe limitations. Therefore, our assessment based on the soil characteristics seemed to accurately reflect the SAV distribution within Chincoteague Bay. During our own work in Chincoteague Bay (describing soils), 14 soils were noted as supporting SAV on the surface or having plant roots within the surface horizon. We were unable to visually observe SAV coverage while describing the soils during the summer months since the water visibility was less than 50 cm due to microalgae blooms. Therefore, we could only make observations about SAV coverage based on the existence of plants or roots collected from these small cores (diameter of 7.6 cm), which were collected during the summer months (the non-peak growing season for SAV). These 14 soils and the soil map units are shown in Figure 6-10. Essentially all of the profiles were located along the eastern side of Chincoteague Bay behind the barrier island and occurred on all of the landforms in that area. These included the storm-surge washover fan flats, storm-surge washover fan slope, barrier coves, shoals, and paleo-flood tidal delta landforms. Eleven pedons were located on soils with slight limitations. Of these pedons, five were located in moderate (40-70%) beds and four were located in dense (>70 %) beds. However, two pedons were located in areas where SAV coverage (as reported by VIMS) was absent. Two pedons were located on soils with moderate limitations in sparse (10-40 %) and dense (>70 %) SAV beds. Only one pedon was located on the western side of the bay on soils with severe limitations. This pedon was described as having 5% roots in the 277 Figure 6-10. Location of soil descriptions made during the summers of 2004 and 2005. Twelve soils were described as supporting SAV on the surface or having plant roots within the surface horizons. 278 surface horizon, however this pedon was located in an area without SAV coverage. We also described eight soil profiles in areas where the VIMS 2004 survey indicated SAV beds were occurring, but we did not observe SAV on these soils. Six of these profiles were located on the eastern side of the bay. Five of these pedons were located on soils with slight limitation and moderate (40-70 %) coverage and the remaining pedon was located on soils with moderate limitation and dense (>70 %) coverage. The other two soils were located on the western side of the bay. These pedons were located on soils with severe limitation for SAV growth and in areas with sparse (10-40 %) and moderate (40-70 %) coverage. Discussion We predicted the suitability of soils in Chincoteague Bay for potential SAV habitat based on previous studies that documented the importance of sulfide concentrations, organic matter, and texture. Comparisons were made between current growth patterns of SAV as reported by VIMS, observations we made during the collection of soil pedons, and the soil characteristics. Based on these comparisons, we assessed the suitability of soils in Chincoteague Bay as potential SAV habitats and determined that three groups of soils had a slight suitability rating for SAV growth: Demas soil series (Sulfic Psammowassents), Thorofare soil series (sandy Haplic Sulfiwassents), and Cottman soil series (coarse-loamy Sulfiwassents). Demas (1998) identified soils on the eastern side of adjacent Sinepuxent Bay that were similar to those on the eastern side of Chincoteague Bay. However, these soils did not support SAV growth and Demas concluded that these soils were too dense and had low fertility levels. 279 In Sinepuxent Bay, SAV grew the best on sites located on the western side of the bay in the shallow mainland coves, which had low amounts of silt and clay, low organic carbon contents, and low concentrations of sulfides. These soils were similar to those we described in Chincoteague Bay on the washover fans but were not quite as sandy. Perhaps more important, the soils in the shallow mainland coves had high concentrations of porewater ammonium. These areas show evidence of groundwater intrusion, which accounts for the low sulfide concentrations and high concentrations of ammonium (Demas, 1998). In our work, several SAV beds were also observed by VIMS on the western side of Chincoteague Bay on fine-silty Fluvic Sulfiwassents, but the coverage was less dense. Based on our assessment, these areas had severe limitations for potential SAV habitats. These soils were loamy or clayey textured (loam, silt loam, silty clay loam, clay loam, and silty clay) and had organic carbon contents >5 g kg -1 . The VIMS SAV coverage on the western side of the bay was located along the coastal and island margins. These areas may have coarser textured surface horizons due to wave erosion and winnowing, which could explain why the SAV coverage was confined to the margins and did not extend out into the bay where the soils are finer textured. Within the center of these areas, the soils were similar to those identified in Sinepuxent Bay that did not contain SAV beds (Demas, 1998). Demas (1998) identified soils in deep mainland coves that had higher quantities of silt and clay, high organic carbon contents (35 g kg -1 ), and high porewater sulfide concentrations. The high sulfide concentrations in these soils were considered to be toxic to SAV and inhibit their growth in these areas. Another possible limitation in these soils is that the silty surfaces in these areas could easily be 280 resuspended by waves or tidal currents that could limit light penetration which would affect SAV growth. Several soils had moderate suitability rating for SAV growth. These soils were coarse-loamy Fluvic Sulfiwassents, fine-silty Fluvic Sulfiwassents, and fine-silty Thapto- histic Sulfiwassents. The coarse-loamy Fluvic Sulfiwasents soils had sandy surface textures and moderately low organic carbon contents, which are favorable for SAV growth. The fine-silty Fluvic Sulfiwassents had severe suitability ratings in other map units, however in the barrier coves these soils had sandy surface textures and lower organic carbon contents, which were more favorable for SAV growth; however below the surface, the textures become finer and the organic carbon contents increase. Therefore these soils were given moderate suitability ratings due to the soil properties below the surface. In contrast to observations in Sinepuxent Bay and Chincoteague Bay, SAV coverage in Ninigret Pond, RI, extended across the barrier coves, lagoon bottom, and flood-tidal delta slope landforms (Bradley and Stolt, 2006). The lagoon bottom and barrier cove landforms are low-energy depositional areas and contained soils which are finer textured, have higher quantities of organic carbon, and higher total nitrogen levels. However, the flood-tidal delta slope landform is a high-energy area and contained soils that are coarser textured with lower organic carbon contents, total nitrogen, and acid volatile sulfides. These coarser soils are more similar to these in Chincoteague Bay where the SAV coverage was dominant. In Ninigret Pond, RI the SAV may be confined to these deeper water landforms due to ice scour during the winter months which would destroy plant life in shallower water (Bradley and Stolt, 2006). 281 An additional soil characteristic, soil salinity, was used by Bradley and Stolt (2006) to explain the presence or absence of eelgrass in Ninigret Pond, RI. They found salinities that ranged from 34 to 44 ppt supported the most eelgrass. They observed coarser textured soils located near the barrier island and loamy soils located near the mainland had salinity levels between 19 and 27 ppt and these areas did not support eelgrass. Zostera marina is found in a wide range of salinity levels (10 to 39 ppt) (McRoy, 1966). Therefore, in Ninigret Pond, RI, the salinity levels should support the growth of Zostera marina and the absence of Zostera marina may be related to another factor. These areas may be receiving groundwater inputs, which has been linked to eelgrass decline due to the higher amounts of nutrients carried in these waters (eutrophication from housing development and agriculture) (Taylor et al., 1995). However, in Sinepuxent Bay the highest SAV biomass was found in areas adjacent to the mainland in areas suspected of receiving groundwater inputs that were high in ammonium and thought to be enhancing SAV growth (Demas, 1998). Conclusions Many studies have highlighted the importance of water quality and light availability for the growth and survival of SAV. However, when these criteria are met SAV growth and survival may still be limited by other physical and chemical properties of the soils. Several other factors have been implicated as factors controlling seagrass populations including water depth, availability of nutrients, toxic material, and soil conditions. However, the factors that affect the success and survival of seagrasses often are overlapping and it becomes difficult to evaluate these factors independently. Soil properties are interrelated with water depth (as a factor of soil formation) and water depth 282 which itself can impact SAV growth by filtering light by suspended materials. It has been documented that the soils can control the success or failure of SAV establishment. The soil properties that have the greatest impact on SAV growth are sulfide content, organic carbon content, and texture. The soil suitability map for potential SAV habitats in Chincoteague Bay, MD, was created using the combination of these three characteristics. Based on our analysis SAV was most abundant on the soils with slight limitations and were almost non existent on soils with severe limitations. The soils with slight limitations had low amounts of silt and clay (sand, loamy sand, and sandy loam textures), low organic carbon contents (0.2 to 7 g kg -1 ), and low concentrations of sulfide minerals (AVS ranged from 0.04 to 0.06 g kg -1 and CRS ranged from 0.08 to 1.81 g kg -1 ). Based on these criteria, the following soils are well suited for SAV growth and success: Demas soil series (Sulfic Psammowassents), Thorofare soil series (sandy Haplic Sulfiwassents), Tizzard soil series (sandy over loamy Haplic Sulfiwassents), and Cottman soil series (coarse-loamy Haplic Sulfiwassents). In Chincoteague Bay these soils are located on the storm-surge washover fan flat, storm-surge washover fan slope, shoal, and paleo-flood tidal delta landforms. 283 Chapter 7: Dissertation Summary and Conclusions This study has provided a comprehensive soil resource inventory for the largest of Maryland?s coastal bays. I have identified several new landforms, increased the data available on subaqueous soils, enhanced the subaqueous soil-landscape models currently available for coastal lagoons, proposed eight new soil series for use in the Mid-Atlantic region, and highlighted the application of subaqueous soils data for the restoration of submerged aquatic vegetation. This inventory of soils for Chincoteague Bay provides information that has important ecological and environmental ramifications regarding their use for specific land uses. By combining this data set with other data regarding benthic flora and fauna and physical properties of the estuary I would be able to develop suitability maps to identify locations for specific land uses, such as shell fish production or dock placement, and to better predict the potential impact of changes to the subaqueous soils and the ecosystem from dredging or shoreline stabilization activities. In this study, we identified and delineated 10 subaqueous landforms based on water depth, slope, landscape shape, geographical setting, and depositional environment. The landforms identified in Chincoteague Bay were similar to subaqueous landforms identified in other Atlantic coastal lagoons. However, we also identified two new landforms, the paleo-flood tidal delta and the submerged wave-cut headland. The paleo- flood tidal delta landform was a relict fan-shaped deposit of sandy sediments that were transported through an active inlet and after the closure of the inlet became a stable 284 landform from which the subaqueous soils formed. The submerged wave-cut headlands were located on the western side of Chincoteague Bay and were produced by coastal wave erosion of headlands which were subsequently submerged by rising sea level or subsidence. The soils located on these landforms were similar to those found in the adjacent mainland coves. The soil-landscape models developed in previous studies were useful in describing most of the soils in Chincoteague Bay. However, we enhanced the models to better accommodate and describe the soils located on the lagoon bottom, storm-surge washover fan slope, and shoal landforms and we also added to the existing model by including the two new landforms identified in Chincoteague Bay. The soils in Chincoteague Bay display systematic variation in physical and chemical properties from the barrier island side to the mainland side of the bay. On the barrier island side of Chincoteague Bay the soils were sandy and had low n values. These are high-energy environments that winnow out the fine sediments and detrital carbon in these settings. Therefore, these soils have low organic carbon and iron contents, which limits the sulfide mineral formation. Due to the low carbon and sulfide contents, these sandy soils were favorable for submerged aquatic vegetation habitat. The past and current distribution of submerged aquatic vegetation in Chincoteague Bay supports this SAV habitat. The sand content decreases when transecting westward from the barrier island to the lagoon bottom. The lagoon bottom was a low-energy environment which is conducive to the formation of finer textured soils with higher quantities of organic carbon and high n values. This low-energy environment possessed the ideal combination of factors to facilitate sulfide mineral formation. These soils have sufficient quantities of organic carbon from detrital sources, such as eelgrass and algae and an iron source as iron oxides 285 sorbed to fine textured mineral sediments. On the mainland side of Chincoteague Bay the soils often contain buried organic horizons which occur at shallower depths closer to the mainland. These are low-energy environments and contain soils that are finer textured, have high n values, and high organic carbon contents. These environments facilitate the formation of sulfide minerals due to the large quantity of oxidizable carbon from the adjacent marshes and in the buried organic horizons and a source of iron as iron oxides sorbed to finer textured mineral sediments. These soils contain the highest organic carbon and sulfide contents in Chincoteague Bay. The soils in the western and central portions of Chincoteague Bay possess several properties which are detrimental to submerged aquatic vegetation. As a result only limited occurrences of SAV beds (only with low densities) have been reported on these soils. The characterization of the soils for a variety of physical and chemical properties enhanced the current data set available for these coastal lagoons. We documented that most of the soils contained sulfidic materials based on moist incubation pH data. However, the moist incubations required a longer time period to identify the presence of sulfidic materials in these soils. When using the current eight week period required by Soil Taxonomy only 57% of the samples displayed a drop in pH below 4, but by doubling the length of time to 16 weeks, 91% of the samples met and maintained the required drop in pH below 4. Therefore, we recommend monitoring the pH for longer than the eight week period currently required by Soil Taxonomy to identify sulfidic materials in these estuarine systems. The n value is an important criterion in classifying soils at the great group level and is used to estimate the fluidity and bearing capacity of the soil. In the field the n values were estimated using the squeeze test for each horizon. The sandy 286 textured soils (fS, LfS, or LS) generally had n values less than 0.7, whereas the finer textured soils (SiCL, SiC, or C) mostly had n values greater than 1. The exceptions to this trend were namely in high density submerged upland soils, such as in the subsoil of submerged wave-cut headlands. However when the n value was calculated based on the equation in Soil Taxonomy, and the percent of sand, silt, clay, organic matter, and water content, the values did not correlate well with the field estimated n value especially for the extremely sandy soils. The field estimated n value is a better predictor of the fluidity and bearing capacity of the soils and is a useful matrix. In contrast, the calculated n values seem to be substantially flawed and may not be of much value as it currently stands for subaqueous soils. Data on porewater salinity through the soil profile provided an interesting perspective on the soil hydrology of these systems. Porewater salinity in surface horizons had values similar to the overlying water column which ranged from 26 to 36 ppt. Salinity within pedons located on the eastern side of Chincoteague Bay remained high with depth with values centered around 26 to 34 ppt. However, pedons located near the mainland tended to show a systematic decrease in salinity with depth. The lower salinity values associated with these areas are likely the result of groundwater discharge into the bay from the surrounding watershed. Obtaining accurate organic carbon content for soils containing calcium carbonate is always problematic, but we thought that our use of Piper?s (1949) methodology would minimize difficulties. It, however, also proved problematic due to the oxidation of organic carbon by sulfurous acid treatment. Once recognized, this was overcome by using a correction factor obtained from soils without calcium carbonate. Measured values for organic carbon were lowest in the sandy soils located on the storm-surge washover fan 287 flat and paleo-flood tidal delta landforms. The profiles that contained buried organic horizons had the highest organic carbon contents within Chincoteague Bay. The lowest quantities (0.7 to 3.6 kg m 2 ) of organic carbon stored in the upper 1 m were found in the sandy soils located on the storm-surge washover fan flat, storm-surge washover fan slope, and paleo-flood tidal delta landforms. The finer textured lagoon bottom, fluviomarine bottom, and barrier cove landforms have moderate quantities (4.0 to 21.0 kg m -2 ) of organic carbon while those in the mainland coves and submerged wave-cut headlands have the highest organic carbon (5.0 to 34.0 kg m -2 ) stored due to the presence of buried organic horizons within the profile. These values fall within the range of organic carbon (6.7 to 17.7 kg m -2 ) stored in subaqueous soils located in Taunton Bay, ME. Generally, the quantities of carbon stored in these subaqueous soils ranged between values obtained from the poorly drained (such as the Othello soil series 6.3 kg m -2 ) and the very poorly drained (such as the Sunken soil series 18.1 kg m -2 ) subaerial soils located on the Delmarva Peninsula. This work should provide additional data for use in regional and carbon budgets of the shallow water estuaries. The calcium carbonate contents are generally low in this environment. The classification of these soils helps provide very important information about the subaqueous soils of Chincoteague Bay to knowledgeable users. When the current edition of Soil Taxonomy (2006) was used, nearly all (98%) of the subaqueous soils were classified as Sulfaquents. The proposed changes to Soil Taxonomy that include a new suborder Wassents seems to better accommodate subaqueous soils. Because the new approach places a higher priority on recognizing sandy textures over the presence of sulfidic materials, thus more information is conveyed in the great group classification. 288 There are currently six soil series approved for subaqueous soils and these series only accommodated 24% of the soils described in Chincoteague Bay. Therefore, eight additional soil series were proposed to accommodate the remainder of the soils at the series level of classification. The proposed series were differentiated based on the presence or absence of organic horizons, textural changes with depth, and n values of horizons within various portions of the profile. Based on previous studies and the soils information collected in Chincoteague Bay we were able to evaluate the suitability of the soils as potential submerged aquatic vegetation habitat. The submerged aquatic vegetation beds are mostly located on soils with low organic carbon contents (0.2 to 7.0 g kg -1 ), low concentration of sulfide minerals (AVS ranged from 0.0 to 0.4 g kg -1 and CRS ranged from 0.07 to 1.76 g kg -1 ) and high quantities of sand (>80 %). Based on these data several soils were identified as having the greatest potential for submerged aquatic vegetation growth and success in healthy estuaries. This was a test case for Chincoteague Bay based on the past and current growth patterns of submerged aquatic vegetation. However, more research is required to determine which properties are most important in restoring submerged aquatic vegetation in degraded estuaries and coastal lagoons. The information provided by this study enriches the current data set available on subaqueous soils and highlights the importance of the use of subaqueous soil data in ecological studies. This data set should be used in conjunction with other ecological studies to in order to identify premium restoration sites for benthic flora and fauna and to locate areas that are able to support engineering structures. 289 List of Appendices Appendix A: Proposed Changes to Soil Taxonomy????????????..290 Appendix B: Landforms, Map Units, and Classification of Soil Pedons????.298 Appendix C: Soil Morphological Descriptions??????????????.308 Appendix D: Total Carbon, Organic Carbon, and Calcium Carbonate Data???468 Appendix E: Moist Incubation pH Data?????????????????484 Appendix F: Salinity Data??????????????????????.492 Appendix G: Moisture Content and Bulk Density Data???????????499 Appendix H: Particle-Size Data?????????.???????????509 290 Appendix A: Proposed Changes to Soil Taxonomy 291 Entisols Key to Suborders Entisols that have a positive water potential at the soil surface for 90% of each day. Wassents Key to Great Groups Wassents that have, in all horizons within 100 cm of the mineral soil surface, an electrical conductivity of <0.2 dS m -1 in a 1:5 by volume mixture of soil and water. Frasiwassents Other Wassents that have less than 35 percent (by volume) rock fragments and a texture of loamy fine sand or coarser in all layers within the particle-size control section. Psammowassents Other Wassents that have sulfidic materials within 50 cm of the mineral soil surface. Sulfiwassents Other Wassents that have, in all horizons at a depth between 20 and 50 cm below the mineral soil surface, both an n value of more than 0.7 and 8 percent or more clay in the fine earth fraction. Hydrowassents Other Wassents that have either 0.2 percent or more organic carbon of Holocene age at a depth of 125 cm below the mineral soil surface or an irregular decrease in content of organic carbon from a depth of 25 cm to a depth of 125 cm or to a densic, lithic, or paralithic contact if shallower. Fluviwassents Other Wassents. Haplowassents Fluviwassents Key to Subgroups Fluviwassents that have sulfidic materials within 100 cm of the mineral soil surface. Sulfic Fluviwassents Other Fluviwassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Fluviwassents 292 Other Fluviwassents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface. Thapto-Histic Fluviwassents Other Fluviwassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. Aeric Fluviwassents Other Fluviwassents. Typic Fluviwassents Frasiwassents Key to Subgroups Frasiwassents that have, in all horizons at a depth between 20 and 50 cm below the mineral soil surface, both an n value of more than 0.7 and 8 percent or more clay in the fine earth fraction. Hydric Frasiwassents Other Frasiwassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Frasiwassents Other Frasiwassents have less than 35 percent (by volume) rock fragments and a texture of loamy fine sand or coarser in all layers within the particle-size control section. Psammic Frasiwassents Other Frasiwassents have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface. Thapto-Histic Frasiwassents Other Frasiwassents that have either 0.2 percent or more organic carbon of Holocene age at a depth of 125 cm below the mineral soil surface or an irregular decrease in content of organic carbon from a depth of 25 cm to a depth of 125 cm or to a densic, lithic, or paralithic contact if shallower. Fluvic Frasiwassents Other Frasiwassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. Aeric Frasiwassents Other Frasiwassents. Typic Frasiwassents 293 Haplowassents Key to Subgroups Haplowassents that have sulfidic materials within 100 cm of the mineral soil surface. Sulfic Haplowassents Other Haplowassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Haplowassents Other Haplowassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. Aeric Haplowassents Other Haplowassents. Typic Haplowassents Hydrowassents Key to Subgroups Hydrowassents that have sulfidic materials within 100 cm of the mineral soil surface. Sulfic Hydrowassents Other Hydrowassents that have, in all horizons at a depth between 20 and 100 cm below the mineral soil surface, both an n value of more than 0.7 and 8 percent or more clay in the fine earth fraction. Grossic Hydrowassents Other Hydrowassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Hydrowassents Other Hydrowassents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface. Thapto-Histic Hydrowassents Other Hydrowassents. Typic Hydrowassents Psammowassents Key to Subgroups Psammowassents that have sulfidic materials within 100 cm of the mineral soil surface. Sulfic Psammowassents 294 Other Psammowassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Psammowassents Other Psammowassents that have either 0.2 percent or more organic carbon of Holocene age at a depth of 125 cm below the mineral soil surface or an irregular decrease in content of organic carbon from a depth of 25 cm to a depth of 125 cm or to a densic, lithic, or paralithic contact if shallower. Fluventic Psammowassents Other Psammowassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. Aeric Psammowassents Other Psammowassents. Typic Psammowassents Sulfiwassents Key to Subgroups Sulfiwassents that have a lithic contact within 100 cm of the mineral soil surface. Lithic Sulfiwassents Other Sulfiwassents that have, in some horizons at a depth between 20 and 50 cm below the mineral soil surface, either or both: 1. An n value of 0.7 or less; or 2. Less than 8 percent clay in the fine-earth fraction. Haplic Sulfiwassents Other Sulfiwassents that have a buried layer of organic soil materials, 20 cm or more thick, that has its upper boundary within 100 cm of the mineral soil surface. Thapto-Histic Sulfiwassents Other Sulfiwassents that have either 0.2 percent or more organic carbon of Holocene age at a depth of 125 cm below the mineral soil surface or an irregular decrease in content of organic carbon from a depth of 25 cm to a depth of 125 cm or to a densic, lithic, or paralithic contact if shallower. Fluvic Sulfiwassents Other Sulfiwassents that have a chroma of 3 or more in 40% or more of the matrix of one or more horizons between a depth of 15 and 100 cm from the soil surface. Aeric Sulfiwassents Other Sulfiwassents. Typic Sulfiwassent 295 Wassists Wassists are subaqueous Histosols. Defined as Histosols that have a positive water potential at the soil surface for 90% of each day. These soils are the second suborder to classify out under Histosols after Folists. The formative element Wass is derived from the German (Swiss) word ?wasser? for water. Key to Great Groups Wassists that have, in all horizons within 100 cm of the mineral surface, an electrical conductivity of <0.2 dS m -1 in a 5/1 by volume mixture of water and soil. Frasiwassists Other Wassists that have sulfidic materials within 50 cm of the mineral soil surface. Sulfiwassists Other Wassists. Haplowassists Frassiwassists Key to Subgroups Other Frassiwassists that: 1. Have more thickness of fibric soil materials than any other kind of organic soil material either: a. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or b. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; and 2. Do not have a sulfuric horizon that has its upper boundary within 50 cm of the soil surface; and 3. Do not have sulfidic materials within 100 cm of the soil surface. Fibric Frasiwassists Other Frasiwassists that have more thickness of sapric soil materials than any other kind of organic soil material either: 1. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or 2. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier. Sapric Frasiwassists 296 Other Frasiwassists Hemic Frasiwassists Sulfiwassists Key to Subgroups Other Sulfiwassists that have more thickness of fibric soil materials than any other kind of organic soil material either: 1. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or 2. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier. Fibric Sulfiwassists Other Sulfiwassists that have more thickness of sapric soil materials than any other kind of organic soil material either: 1. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or 2. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier. Sapric Sulfiwassists Other Sulfiwassists. Hemic Sulfiwassists Haplowassists Key to Subgroups Other Haplowassists that have more thickness of fibric soil materials than any other kind of organic soil material either: 1. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or 2. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier. Fibric Haplowassists 297 Other Sulfiwassists that have more thickness of sapric soil materials than any other kind of organic soil material either: 1. In the organic parts of the subsurface tier if there is no continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier; or 2. In the combined thickness of the organic parts of the surface and subsurface tiers if there is a continuous mineral layer 40 cm or more thick that has its upper boundary within the subsurface tier. Sapric Haplowassists Other Sulfiwassists. Hemic Haplowassists 298 Appendix B: Landforms, Map Units, and Classification of Soil Pedons 299 Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB01 Storm-surge washover fan flat De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB02 Storm-surge washover fan flat, scour channel De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB03 Storm-surge washover fan flat De? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB04 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB05 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB06 Mainland Cove Sp? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB07 Storm-surge washover fan flat De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB08 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB09 Mainland cove Sp? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Unnamed C CB10 Barrier cove Mm? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB11 Submerged wave- cut headland Sp? Fine, Thapto-Histic Sulfaquents (Fine, Thapto-Histic Sulfiwassents) Southpoint Tax. CB12 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB13 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB14 Lagoon bottom Ct? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB15 Lagoon bottom Ct? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB16 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas 300 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB17 Storm-surge washover fan flat, scour channel De? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB18 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB19 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB20 Lagoon bottom Tg? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Truitt Tax. CB21 Submerged wave- cut headland Sp? Fine-loamy, Thapto-Histic Sulfaquents (Fine-loamy, Thapto-Histic Sulfiwassents) Southpoint Tax. CB22 Submerged wave- cut headland Sp? Fine-loamy, Thapto-Histic Sulfaquents (Fine-loamy, Thapto-Histic Sulfiwassents) Southpoint Tax. CB23 Mainland cove Sp? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Southpoint Tax. CB24 Mainland cove Sp? Coarse-silty, Thapto-Histic Sulfaquents (Coarse-silty, Thapto-Histic Sulfiwassents) Southpoint Tax. CB25 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB26 Mainland cove Sp? Fine, Haplic Sulfaquents (Fine, Haplic Sulfiwassents) Southpoint Tax. CB27 Mainland cove Sp? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB28 Storm-surge washover fan flat De? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB29 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB30 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB31 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles 301 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB32 Mainland cove Sp? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Truitt Tax. CB33 Mainland cove Sp? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Aeric Sulfiwassents) Unnamed C CB34 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB35 Submerged wave-cut headland Tr? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB36 Submerged wave-cut headland Tr? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB37 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB38 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB39 Mainland Cove Tr? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB40 Lagoon bottom Tg? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB41 Lagoon bottom Tg? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB42 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB43 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB44 Storm-surge washover fan flat De? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB45 Storm-surge washover fan flat De? Sandy over loamy, Haplic Sulfaquents (Sandy over loamy, Haplic Sulfiwassents) Tizzard CB46 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles 302 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB47 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB48 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB49 Lagoon bottom Tg? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents Sinepuxent CB50 Lagoon bottom Tg? Coarse-silty, Sulfic Hydraquents (Coarse-silty, Sulfic Hydrowassents) Unnamed B CB51 Submerged wave-cut headland Tr? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB52 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB53 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB54 Storm-surge washover fan flat De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB55 Storm-surge washover fan slope Th? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB56 Storm-surge washover fan flat De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB57 Barrier cove Mm? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB58 Lagoon bottom Ct? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents Sinepuxent CB59 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB60 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB61 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB62 Barrier cove Mm? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB63 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB64 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor 303 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB65 Storm-surge washover fan slope Th? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB66 Lagoon bottom Ct? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB67 Shoal De? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB68 Shoal De? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB69 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB70 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB71 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB72 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB73 Mainland cove Sp? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Cottman CB74 Paleo-flood tidal delta Dm? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB75 Lagoon bottom Ct? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB76 Paleo-flood tidal delta Dm? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB77 Paleo-flood tidal delta Dm? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB78 Lagoon bottom Ct? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB79 Lagoon bottom Ct? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB80 Fluviomarine bottom Co? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Aeric Sulfiwassents) Unnamed C CB81 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB82 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB83 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB84 Mainland cove Tr? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt 304 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB85 Mainland cove Tr? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB86 Mainland cove Tr? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Southpoint Tax. CB87 Submerged wave-cut headland Tr? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB88 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB89 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB90 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB91 Fluviomarine bottom Co? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB92 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB93 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB94 Fluviomarine bottom Co? Fine, Typic Sulfaquents (Fine, Fluvic Sulfiwassents) Coards CB95 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB96 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB97 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB98 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB99 Lagoon bottom Tg? Fine-silty, Thapto-Histic Sulfaquents (Fine-silty, Thapto-Histic Sulfiwassents) Southpoint CB100 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB101 Mainland cove Sp? Fine-silty, Thapto-Histic Sulfaquents (Fine-silty, Thapto-Histic Sulfiwassents) Southpoint CB102 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB103 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB104 Lagoon bottom Tg? Fine-loamy, Haplic Sulfaquents (Fine-loamy, Haplic Sulfiwassents) Truitt Tax. 305 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB105 Submerged wave-cut headland Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Southpoint Tax. CB106 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB107 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB108 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB109 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB110 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB111 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB112 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB113 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB114 Lagoon bottom Tg? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB115 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB116 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB117 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB118 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB119 Submerged wave-cut headland Si? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Typic Sulfiwassents) Sinepuxent CB120 Mainland cove Si? Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Typic Sulfiwassents) Sinepuxent CB121 Mainland cove Si? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB122 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB123 Shoal De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas 306 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB124 Submerged wave-cut headland Sp? Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) Southpoint Tax. CB125 Shoal De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB126 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB127 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB128 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB129 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB130 Fluviomarine bottom Co? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Coards CB131 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) Thorofare CB132 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB133 Shoal De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB134 Submerged wave-cut headland Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB135 Submerged wave-cut headland Sp? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB136 Submerged wave-cut headland Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB137 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB138 Storm-surge washover fan slope Th? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB139 Shoal De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas CB140 Shoal De? Sandy, Haplic Sulfaquents (Sulfic Psammowassents) Demas 307 Appendix B: Continued. Pedon Landform Soil Map Unit Current Soil Classification (Proposed Soil Classification) Series CB141 Lagoon bottom Tg? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Tingles CB142 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Truitt CB143 Mainland cove Sp? Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) Middlemoor CB144 Submerged wave-cut headland Sp? Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) Figgs CB145 Submerged wave-cut headland Sp? Fine-silty, Terric Sulfisaprists (Sapric Sulfiwassists) Tumagan CB146 Submerged wave-cut headland Sp? Fine-silty, Terric Sulfisaprists (Sapric Sulfiwassists) Tumagan 308 Appendix C: Soil Morphological Descriptions 309 Abbreviations Used in Soil Morphological Descriptions Horizon Nomenclature: Based on accepted master horizons and suffix notations in the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) and Keys to Soil Taxonomy, 10th ed. (Soil Survey Staff, 2006). USDA Textural Class: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) S (sand), cS (coarse sand), fS (fine sand), LS (loamy sand), LfS (loamy fine sand), SL (sandy loam), fSL (fine sandy loam), vfSL (very fine sandy loam), SCL (sandy clay loam), L (loam), SiL (silt loam), SiCL (silty clay loam), CL (clay loam), SiC (silty clay), C (clay), MkSiL (mucky silt loam), MkL (mucky loam), Mk (muck). Feature Abundance: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) f (faint), d (distinct), p (prominent) Structure: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) Grade: 0 (none), 1 (weak), 2 (moderate) Shape: sg (single grain), ma (massive), gr (granule), sbk (subangular blocky), pr (prismatic) Moist Consistence: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) l (loose), vfr (very friable), fr (friable), fi (firm) Wet Consistence: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) ns (non sticky), ss (slightly sticky), ms (moderately sticky), vs (very sticky) np (non plastic), vp (very plastic) n value: From the Keys to Soil Taxonomy, 10th ed. (Soil Survey Staff, 2006) Values based on ?squeeze test?: <0.7 (material does not flow between fingers when squeezed), 0.7-1 (material flows with some difficulty between fingers when squeezed), >1 (material flows easily between fingers when squeezed), >>1 (material runs through fingers without squeezing) 310 Boundary: From the Field Book for Describing and Sampling Soils, Version 2.0 (Schoenberger et al., 2002) a (abrupt), c (clear), g (gradual) 311 Sample CB01 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 07? 05.57? N, 75? 12? 02.62? W Water Depth 69 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 14 a S fS 10Y 3/1 0 sg lo <0.7 None Cg1 76 a S fS 10Y 5/1 0 sg lo <0.7 Strong Cg2 103 c fS fS 5GY 4/1 10 10YR 3/2 0 ma vfr <0.7 1 Strong Cg3 170 c LfS fS 5GY 4/1 0 ma vfr <0.7 Strong Cg4 210 - fSL LfS 5GY 3/1 0.5 10YR 3/2 0 ma vfr <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 17 August 2004 at 9:25 am Sampled using a vibracorer; depth inside core 93 cm, depth outside core 86 cm Large clam shell at 76 cm Krotovina at 28 cm, 2cm wide filled with N 2.5/ soil 312 Sample CB02 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 06? 37.84? N, 75? 12? 41.44? W Water Depth 177 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 14 a fS/LfS 10Y 2.5/1 0 ma vfr <0.7 1 Strong Cg/A 30 c LfS 5GY 3/1 10Y 2.5/1 (10%) 0 ma vfr <0.7 Strong Cg1 73 c LfS/fSL 5GY 3/1 0 ma fr <0.7 Strong Cg2 103 c LfS/fSL 5GY 3/1 4 10YR 3/3 0 ma vfr <0.7 5 Strong Cg3 136 - fS 5GY 3/1 0 ma vfr <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 17 August 2004 at 11:54 am Sampled using a vibracorer; depth inside core 184 cm, depth outside core 177 cm Presence of decomposed eelgrass on surface 313 Sample CB03 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 06? 27.96? N, 75? 13? 02.91? W Water Depth 109 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 8 a S 5Y 2.5/1 0 ma lo <0.7 Strong Cg1 43 a S 5Y 4/1 5Y 2.5/1 (15%) 0 ma lo <0.7 Strong Cg2 86 c fS 5Y 2.5/1 0 ma vfr 0.7-1 Strong 2Cg3 109 c fSL/L 10Y 3/1 1 10YR 3/2 0 ma fr <0.7 15 Strong 2Cg4 134 g fSL 5GY 3/1 1 10YR 3/2 0 ma fr <0.7 Strong 2Cg5 149 - LfS 10GY 3.5/1 0 ma vfr <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 17 August 2004 at 1:43 pm Sampled using a vibracorer; depth inside core 104 cm, depth outside core 97 cm 314 Sample CB04 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 07?27.48? N, 75? 16? 37.84? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 6 c SiC/SiCL 10GY 2.5/1 0 ma vfr >1 Strong Cg1 32 g SiC/SiCL SiL 5GY 2.5/1 0 ma vfr >1 1 Strong Cg2 111 c SiC/SiCL SiL/SiCL 5GY 3/1 0 ma vfr >1 1 Strong Cg3 149 - SiC/SiCL SiCL 10GY 3.5/1 1-2 10YR 3/3 0 ma vfr >1 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 18 August 2004 at 8:14 am Sampled using a McCauley sampler 315 Sample CB05 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 07? 33.36? N, 75? 16? 53.29? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 6 a SiC/SiCL N 3/ 0 ma vfr >1 Strong A2 37 c SiC/SiCL N 2.5/ 0 ma vfr >>1 Strong Cg1 94 g SiC/SiCL 5GY 3/1 1 10YR 3/2 0 ma vfr >1 1 Strong Cg2 152 - SiC/SiCL 10Y 3.5/1 0 ma vfr >1 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 18 August 2004 at 8:40 am Sampled using a McCauley sampler A2 had a ?jelly? consistence 316 Sample CB06 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 07? 39.00? N, 75? 17? 07.46? W Water Depth 215 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC/SiCL 10Y 3/1 0 ma vfr >1 Strong Cg1 59 a SiC/SiCL SiCL 5GY 2.5/1 0 ma vfr >1 Strong 2Cg2 81 c fSl/SCL fSL 10Y 3/1 0 ma fr 0.7-1 0.5 Strong 2Cg3 107 c fSl LfS 10Y 4/1 1 10YR 3/2 0 ma vfr 0.7-1 Strong 2Cg4 125 a fSL 5Y 5/1 0 ma vfr 0.7-1 Strong 2Cg5 153 - LfS 5Y 6/1 0 ma vfr <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and P.T. Morton; 18 August 2004 at 8:54 am Sampled using a McCauley sampler 317 Sample CB07 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 08? 23.89? N, 75? 12? 01.00? W Water Depth 72 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 3 a LfS 5Y 4/1 0 ma vfr <0.7 5 None Cg/A 19 a fS 10Y 5/1 5Y 3/1 (10%) 0 sg lo <0.7 Strong Cg1 56 c fS 5GY 3.5/1 0 sg lo <0.7 Strong Cg2 110 c LfS 5GY 3/1 2 10YR 3/2 0 ma vfr <0.7 3 Strong Cg3 132 a LfS 5GY 2.5/1 0 ma vfr <0.7 0.5 Cg4 154 - S 5GY 4/1 0 sg lo <0.7 Remarks: Profile description by D.M. Balduff, C.C. Coppock, A.L. Gray; 23 August 2004 at 11:08 am Sampled using a vibracorer; depth inside core 150 cm, depth outside core 148 cm Eelgrass on surface Clam shell in Cg2; Mud Snail shell in Cg3 318 Sample CB08 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 08? 49.72? N, 75? 12? 44.89? W Water Depth 131 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 4 a S 5Y 4/2 0 sg lo <0.7 None A2 24 c S 5Y 3.5/1 0 sg lo <0.7 Strong Cg1 37 c fS 10Y 3/1 0 sg lo <0.7 0.5 Strong Cg2 47 c LfS 10Y 3/1 0 ma vfr <0.7 Strong Cg3 84 g LfS 10Y 3/1 0 ma vfr <0.7 1 Strong Cg4 134 c S 5GY 4/1 1 10YR 3/2 0 sg lo <0.7 Strong 2Cg5 142 - fSL 5GY 4/1 0 ma vfr 0.7-1 Strong Remarks: Profile description by D.M. Balduff, C.C. Coppock, A.L. Gray; 23 August 2004 at 1:09 pm Sampled using a vibracorer; depth inside core 151 cm, depth outside core 146 cm 319 Sample CB09 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 07? 41.93? N, 75? 17? 35.15? W Water Depth 175 cm Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Abun.% Color Gr. Shape Moist Const. n value Shells % Intensity of H 2 S A1 2 a LS/Sl - 5Y 4/1 0 ma vfr 0.7-1 None A2 16 a LS/SL LfS 10Y 3/1 ma vfr 0.7-1 1 None Cg1 22 c LS LfS 10Y 3/1 0 ma vfr <0.7 None Cg2 42 c LfS fSL 5Y 4/1 5 f,D 10YR 3/3 0 ma vfr <0.7 None Cg/Bwb 53 c SL LfS/fSL 5Y 5/1 5 P 3 P 10YR 4/4 10YR 5/6 8 m,D 10YR 3/3 0 ma vfr <0.7 None 2Bgb 76 c SL fSL 5Y 4/2 7 D 2 P 10YR 4/4 N 2.5/ 2 f,D 10YR 3/3 0 ma vfr <0.7 None 2Bwb1 98 c LS LfS 2.5Y 4/3 20 D 5 P 10YR 4/6 N 2.5/ 0 ma vfr <0.7 None 2Bwb2 108 c SL SL 2.5Y 4/3 10 P 15 D 5Y 5/1 10YR 5/6 0 ma vfr <0.7 None 2BCgb 118 a LS LfS 5Y 5/1 2 D 3 P 10Y 6/1 10YR 4/6 0 ma vfr <0.7 None 2Cgb1 133 a SL fSL 5GY5.5/1 8 P 10YR 4/6 0 ma vfr <0.7 None 2Cgb2 151 - S LfS 5GY 6/1 0 sg vfr <0.7 None Remarks: Profile description by D.M. Balduff, C.C. Coppock, A.L. Gray; 23 August 2004 at 3:30 pm. Sampled using a vibracorer; depth inside core 252 cm, depth outside core 249 cm. 320 Sample CB10 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 05? 33.68? N, 75? 12? 57.21? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 17 a LfS fS 10Y 3/1 5Y 4/2 (3%), 0 ma vfr <0.7 2 Strong Cg1 51 c fS fS 5Y 3.5/1 0 sg lo <0.7 Strong 2Cg2 64 a fSL LfS 10Y 3/1 0 ma vfr <0.7 2 Strong 2Cg3 84 c SL/L fSL 10Y 3/1 0 ma vfr 0.7-1 3 Strong 2Cg4 89 a LS LfS 10Y 3/1 1 f,D 10YR 3/2 0 ma vfr <0.7 Strong 3Cg5 134 - S fS 10Y 4/1 0 sg lo <0.7 1 Strong Remarks: Profile description by D.M. Balduff, C.C. Coppock, and A.L. Gray; 24 August 2004 at 9:30 am Sampled using a vibracorer; depth inside core 173 cm, depth outside core 163 cm Eelgrass on surface Large clam shell Cg3 Krotovina at 33 cm, 2cm wide filled with N 2.5/ soil 321 Sample CB11 Fine, Thapto-Histic Sulfaquents (Fine, Thapto-Histic Sulfiwassents) 38? 06? 34.32? N, 75? 18? 19.96? W Water Depth 140 cm Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Abun.% Color Gr. Shape Moist Const. n value Shells % Intensity of H 2 S A1 2 a fSL - 5Y 3/1 0 ma vfr >1 Strong A2 12 a fSL LfS/fSL N 2.5/ 0 ma vfr >1 Strong 2Cg1 36 g SiCL/ SiC SiCL 10Y 3/1 0 ma vfr >>1 Strong 2Cg2 56 a SiCL/ SiC SiCL 10Y 3/1 3 f,D 10YR 3/2 0 ma vfr >>1 Strong Oab1 83 c MK - 7.5YR 2.5/1 5 m,D 2.5Y 5/6 0 Strong Oab2 109 a MK - 10YR 2/1 5 m,D 2.5Y 5/6 0 Strong 3Ab 115 a MkL CL N 2.5/ 0 ma vfr >>1 Strong 3Cgb 122 - SiCL L 10YR 4/1 1 f,P 5Y 5/1 3 f, D 2.5Y 5/6 0 ma vfr 0.7-1 Strong Remarks: Profile description by D.M. Balduff, C.C. Coppock, and A.L. Gray; 24 August 2004 at 2:05 am Sampled using a vibracorer; depth inside core 185 cm, depth outside core 180 cm Bands of 10Y 3/1 mineral material 1cm thick in Oab1. 322 Sample CB12 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 06? 28.45? N, 75? 13? 17.17? W Water Depth 130cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a S 5Y 4/1 0 sg lo <0.7 None A2 12 c S N 3/ 0 sg lo <0.7 None Cg1 56 a S N 3.5/ 0 sg lo <0.7 2 Strong Cg2 78 a fS 5GY 4/1 5 f,D 10YR 3/2 0 sg lo <0.7 Strong 2Cg3 102 c fSL 5GY 3.5/1 12 f,D 10YR 3/2 0 ma vfr <0.7 Strong 2Cg4 109 c fSL/L 5GY 3.5/1 1 f,D 10YR 3/2 0 ma vfr >1 2 Strong 2Cg5 126 c fSL/L 5GY 3.5/1 0 ma vfr 0.7-1 Strong 2Cg6 151 - fSL/L 5GY 3/1 3 f,D 10YR 3/2 0 ma vfr 0.7-1 Strong Remarks: Profile description by D.M. Balduff and C.C. Coppock; 25 August 2004 at 9:30 am. Sampled using a vibracorer; depth inside core 156 cm, depth outside core 158 cm 323 Sample CB13 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 06? 29.91? N, 75? 13? 23.23? W Water Depth 166cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 5 c fS 5Y 4/1 0 sg lo <0.7 1 None A2 38 c fS N 3/ 0 sg lo <0.7 0.5 None Cg1 62 a fS N 3.5/ 0 sg lo <0.7 0.5 None 2Cg2 78 c fSL 5GY 3/1 1 f,D 10YR 3/2 0 ma vfr <0.7 Strong 2Cg3 98 c fSL 5GY 3.5/1 0.5 f,D 10YR 3/2 0 ma vfr <0.7 Strong 2Cg4 134 c fSL 5GY 3.5/1 0.5 f,D 10YR 3/2 0 ma vfr <0.7 0.5 Strong 3Cg5 149 a LfS 5GY 3.5/1 0.5 f,D 10YR 3/2 0 ma vfr <0.7 Strong 3Cg6 182 - S 5GY 4/1 0 sg lo <0.7 2 None Remarks: Profile description by D.M. Balduff, C.C. Coppock; 25 August 2004 at 11:47 am. Sampled using a vibracorer; depth inside core 209 cm, depth outside core 205 cm Scallop shell at 60 cm in Cg1 324 Sample CB14 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 06? 37.08? N, 75? 13? 49.42? W Water Depth 255 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 10 c fSL 5GY 3/1 0 ma vfr >1 Strong A2 25 - fSL 5GY 4/1 0 ma vfr >1 Strong Remarks: Profile description by D.M. Balduff, C.C. Coppock; 25 August 2004 at 1:27 pm. Sampled using a McCauley sampler (Could not go past 25 cm) 325 Sample CB15 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 06? 50.03? N, 75? 14? 28.87? W Water Depth 290cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 13 c fSL 5GY 3/1 0 ma vfr >1 Strong Cg1 37 c L 5GY 3/1 0 ma vfr >1 1 Strong Cg2 79 c fSL 5GY 4/1 1 f,D 10YR 3/2 0 ma vfr 0.7-1 Strong Cg3 109 - fSL 5GY 3.5/1 0 ma vfr 0.7-1 1 Strong Remarks: Profile description by D.M. Balduff, C.C. Coppock; 25 August 2004 at 3:30 pm. Sampled using a McCauley sampler (could not go deeper than 110 cm). 326 Sample CB16 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 07? 50.15? N, 75? 12? 55.35? W Water Depth 172 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fS - 5Y 4/2 0 ma NSNP <0.7 None A2 22 c fS fS 10Y 3/0.5 0 ma NSNP <0.7 Strong Cg1 37 g fS fS 10Y 3/1 0 ma NSNP <0.7 Strong Cg2 67 c LfS/fSL LfS 10Y 3/1 1 f,P 10YR 3/4 0 ma NSNP <0.7 Strong Cg3 80 c LfS fS 2.5GY 3.5/1 0 ma NSNP <0.7 3 Strong Cg4 114 c fS fS 5GY 4/0.5 0 ma NSNP <0.7 Strong Cg5 187 c LfS fS 10Y 3/1 0 ma NSNP <0.7 1 Strong Cg6 215 - fS fS 5GY 4/0.5 0 ma NSNP <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and M.H. Stolt; 21 September 2004 at 10:59 am. Sampled using a vibracorer; depth inside core 177 cm, depth outside core 170 cm. 327 Sample CB17 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 07? 51.75? N, 75? 11? 38.86? W Water Depth 100 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 8 a LfS fS 7.5Y 3/0.5 0 ma NPNS <0.7 - Cg/A 32 c LfS fS 7.5Y 4/0.5 (70) 7.5Y 3.0.5 (30) 0 ma NPNS <0.7 1 - 2Cg1 54 c L fSL 2.5GY 3/1 2 f,P 10YR ? 0 ma VS <0.7 1 - 2Cg2 77 a fSL LfS 2.5GY 3/1 1 f,P 2.5Y 5/4 0 ma NPSS <0.7 1 - 3Cg3 102 a S fS 10Y 5/1 N 2.5/ (5) 0 ma NPNS <0.7 - 3Cg4 148 - fS fS 10Y 4/0.5 0 ma NPNS <0.7 - Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and M.H. Stolt; 21 September 2004 at 1:20 pm. Sampled using a vibracorer; depth inside core 158 cm, depth outside core 143 cm. 328 Sample CB18 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 08? 19.95? N, 75? 14? 43.10? W Water Depth 270 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 8 a SiCL/SiC - 10Y 2.5/0.5 0 ma VS >>>1 None Cg 245 - SiCL/SiC SiCL/CL 10Y 3/1 0 ma VS >>1 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and M.H. Stolt; 21 September 2004 at 3:00 pm. Sampled using a McCauley sampler. Oxidized zone 2mm thick. Sandy layer with shells from 204-208 cm. 329 Sample CB19 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 08? 08.52? N, 75? 14? 17.82? W Water Depth 280 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 9 a SiCL/SiC 10Y 2.5/0.5 0 ma VS >>1 None Cg1 38 a SiCL/SiC 10Y 3/1 0 ma VS >>1 None 2Cg2 50 - L 10Y 3/1 0 ma SS <0.7 2 None Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and M.H. Stolt; 21 September 2004 at 4:00 pm. Sampled using a McCauley sampler. Worm tubes on surface. 330 Sample CB20 Fine-loamy, Haplic Sulfaquents (Fine-loamy, Haplic Sulfiwassents) 38? 08? 16.28? N, 75? 14? 30.77? W Water Depth 275 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 8 a SiCL 10Y 2.5/1 0 ma >1 Cg1 32 c SiC/SiCL 10Y 3/1 0 ma >1 2Cg2 60 c fSL 10Y 3/0.5 0 ma <0.7 2 2Cg3 115 c fSL 10Y 3/0.5 0 ma 0.7-1 1 3Cg4 153 a L 10Y 3/1 0 ma 0.7-1 1 3Oab 184 a MK 5YR 2.5/2 Trace Strong 3Ab 193 c SiL/L 2.5Y 2.5/1 2 f,P 7.YR 4/3 0 ma <0.7 Strong 3Cgb 200 - SiL/SiCL 10Y 5/1 2 f,P 2.5YR 4/3 0 ma <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, and M.H. Stolt; 21 September 2004 at 4:10 pm. Sampled using a McCauley sampler. Worm tubes and razor clam on surface. 331 Sample CB21 Fine-loamy, Thapto-Histic Sulfaquents (Fine-loamy, Thapto-Histic Sulfiwassents) 38? 09? 13.34? N, 75? 16? 37.98? W Water Depth 173 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SiL/SiCL CL 5Y 4/2 0 ma >1 None A2 18 a SiL/SiCL CL 10Y 2.5/0.5 0 ma >1 None Oab 58 a MK - 10YR 2/1 Strong Ab 62 c L L 2.5Y 3/2 1 m,P 10YR 3/4 1 f,m gr <0.7 None BAgb 71 c L L 2.5Y 4/1 5 m,P 2.5Y 4/3 1 m sbk <0.7 None Btgb 96 a SiCL C N 3.5 10Y 3/1 (15) 7 m,P 2.5Y 4/3 2 m pr m sbk <0.7 None 2Cgb 134 - S LfS 10Y 6/1 0 sg lo <0.7 None Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 8:37 am. Sampled using a vibracorer; depth inside core 266 cm, depth outside core 262 cm. 332 Sample CB22 Fine-loamy, Thapto-Histic Sulfaquents (Fine-loamy, Thapto-Histic Sulfiwassents) 38? 09? 14.38? N, 75? 16? 44.63? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a L 5Y 4/2 0 ma >1 A2 9 a L N 2.5/ 0 ma >1 Cg 28 a L 10Y 2.5/0.5 30 m,P 10YR 3/4 0 ma >1 Oab 50 a MK 10YR 2/1 Ab 58 c L 2.5Y 3/2 5 f,P 10YR 3/4 0 ma 0.75 Cgb 102 - CL 2.5Y 4/1 3 f,P 2.5Y 4/3 0 ma 0.75 Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 10:51 am. Sampled using a McCauley sampler. 333 Sample CB23 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 08? 50.48? N, 75? 17? 04.40? W Water Depth 149 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 9 a LfS 5Y 3/0.5 0 ma NSNP <0.7 Cg/A 21 c LfS 10Y 3.5/0.5 5Y 3/1.5 (25) 0 ma NSNP <0.7 2 Cg1 40 c LfS 10Y 3/0.7 0 ma NSNP <0.7 Cg2 56 a S 5Y 4/1 10Y 3/0.7 (40) 0 NSNP <0.7 Oab1 107 a MK 10YR 2/2 Strong Oab2 137 a MK 10YR 2/1 Strong A/C 146 - MK fSL 10YR 2/1 3 f,D 10YR 3/4 0 ma NSNP 0.7-1 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 11:15 am. Sampled using a vibracorer; depth inside core 160 cm, depth outside core 150 cm. Oxidized surface 1 cm thick 5Y 4/2. Lenses of 10Y 5/1 in A/C horizon. 334 Sample CB24 Coarse-loamy, Thapto-Histic Sulfaquents (Coarse-loamy, Thapto-Histic Sulfiwassents) 38? 07? 55.29? N, 75? 17? 27.17? W Water Depth 155 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fSL 5Y 4/2 0 ma 0.75 A2 22 c fSL N 3/ 0 ma 0.75 Trace O/C 50 c MK SiL 10YR 3/2 50 m,D 10YR 3/4 0 ma >1 Strong C/O 71 a MK SiL 2.5Y 4/1 40 m,D 10YR 3/4 0 ma >1 Strong Oab1 97 c MK 10YR 3/2 Strong Oab2 133 a MK 10YR 2/1 Strong Ab 139 a fSL 2.5Y 2.5/1 0 ma 0.7-1 Strong Cgb 152 - SL 10Y 3/0.5 0 ma <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 1:00 pm. Sampled using a McCauley sampler. 335 Sample CB25 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 07? 50.48? N, 75? 17? 34.90? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 15 c SiCL/SiC 10Y 2.5/0.5 0 ma VS >>1 Strong Cg1 40 c SiCL/SiC 10Y 3/1 5 m,P 10YR 4/4 0 ma VS >>1 Strong Cg2 250 - SiCL/SiC 10Y 3/1 1 m,P 10YR 4/4 0 ma VS >>1 1 Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 1:40 pm. Sampled using a McCauley sampler. 336 Sample CB26 Fine, Haplic Sulfaquents (Fine, Haplic Sulfiwassents) 38? 07? 10.50? N, 75? 17? 38.37? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 2 a S 2.5Y 4/2 0 ma <0.7 Strong Cg 28 a S fS 10Y 2.5/1 0 ma <0.7 Strong 2A? 50 c MK SiL SiC N 2.5/ 5 m,P 10YR 3/1 0 ma 0.7-1 Strong 2C?g 70 c SiL SiC 10Y 3/1 5 m,P 10YR 3/1 0 ma >1 Strong 2C/O 103 c SiL/SiCL 10Y 2.5/1 20 m,P 10YR 3/1 0 ma >1 Strong 2Oab 132 c MK 7.5YR 2.5/1 Strong 2Ab 137 c MK SiL CL 10YR 2/1 1 sbk <0.7 Strong 2Btg 150 - CL CL 2.5Y 2.5/1 1 sbk <0.7 Strong Remarks: Profile description by D.M. Balduff, M.C. Rabenhorst, M.H. Stolt, and P. King; 22 September 2004 at 11:15 am. Sampled using a vibracorer; depth inside core 155 cm, depth outside core 113 cm. Large wood fragment found at 150 cm. 337 Sample CB27 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 07? 12.84? N, 75? 17? 25.08? W Water Depth 190 cm Boundary USDA Texture Redoximorphic Features Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a L 10Y 3/1 0 ma vsvp > 1 1 Strong Cg1 16 c L 5GY 3/1 0 ma vsvp > 1 Strong Cg2 28 c L 5GY 2.5/1 0 ma vsvp > 1 Strong 2Cg3 43 c SL 5Y 5/2 30 p 15 d 10YR 4/4 N 5.5 0 ma nsnp < 0.7 None 2Cg4 54 c fSL 5Y 5/2 20 p 2.5 Y 5/4 0 ma ns p < 0.7 None 2Cg5 62 - LS 5Y 5/1 0 ma ns np < 0.7 None Remarks: Profile description by D.M. Balduff; 7 June 2005 at 2:20 pm. Sampled using a vibracorer; depth inside core 245 cm, depth outside core 240 cm 338 Sample CB28 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 09? 30.3? N, 75? 12? 19.6? W Water Depth 50 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 10 c SL 5Y 3/1 10Y 4/1 30% 0 ma ms < 0.7 1 Strong Cg1 36 c SL 10Y 4.5/1 trace 10YR 3/3 0 ma ms < 0.7 Strong Cg2 50 a SL 10Y 3.5/1 1% p 10YR 3/3 0 ma ms < 0.7 1 Strong Cg3 78 a fSL 10Y 3.5/1 3% p 10YR 3/3 0 ma vs sp > 1 Strong 2Cg4 109 - LfS 10Y 4.5/1 0 sg ns < 0.7 1 Strong Remarks: Profile description by D.M. Balduff, 8 June 2005 at 9:00 am. Sampled using a vibracorer; depth inside core 190 cm, depth outside core 175 cm. 339 Sample CB29 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 09? 29.2? N, 75? 13? 00.1? W Water Depth 190 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 fSL 5Y 3/1 0 ma vs vp > 1 1 Strong Cg1 6 fSL 5Y 2.5/1 0 ma vs vp > 1 1 Strong Cg2 24 fSL N 3 0 ma msmp < 0.7 tr Strong Cg3 89 SL LfS 10Y 3/1 0 ma ss np < 0.7 tr Strong 2Ab 111 LS fS 5GY 3/1 0 sg ns np < 0.7 35 Strong 2Cgb 159 LS N 4 0 sg ns np < 0.7 2 Strong Remarks: Profile description by D.M. Balduff, 8 June 2005 at 9:45 am. Sampled using a vibracorer; depth inside core 235 cm, depth outside core 230 cm. 340 Sample CB30 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 09? 36.78? N, 75? 14? 45.12? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 1 SiL/SiCL 10Y 4/1 0 ma > 1 Strong A2 17 SiL/SiCL 5GY 3/1 0 ma > 1 2 Strong Cg1 102 SiL/SiCL 5GY 3/1 3% P 10YR 3/3 0 ma > 1 Strong Cg2 150 SiL/SiCL 10Y 3/1 0 ma > 1 Strong Remarks: Profile description by D.M. Balduff, 8 June 2005 at 1:10 pm. Sampled using a McCauley sampler. 341 Sample CB31 Fine, Haplic Sulfaquents (Fine, Haplic Sulfiwassents) 38? 09? 21.7? N, 75? 15? 32.7? W Water Depth 180 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiC 10Y 3.5/1 0 ma vs >> 1 None A2 22 c SiC 5GY 2.5/1 0 ma vs >> 1 5 Weak Cg1 62 c/g SiC 5GY 3/1 0 ma vs >1 None Cg2 112 a SiC 5GY 3/1 0 ma vs >1 Strong Cg3 156 c SiC 5GY 3/1 0 ma vs >1 30 Strong Cg4 185 - SiC 5GY 3.5/1 0 ma vs >1 1 Strong Remarks: Profile description by D.M. Balduff, 9 June 2005 at 9:47 am. Sampled using a McCauley sampler. 342 Sample CB32 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 10? 23.2? N, 75? 15? 58.7? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 6 a CL/C 10Y 3/1.5 0 ma vs >>1 1 None A2 21 c CL/C 10Y 3/1 0 ma vs >1 1 Weak Cg1 38 c CL/C 10Y 3/1 0 ma vs >1 1 Weak Cg2 62 c CL/C 10Y 3/1 0 ma vs >1 1 Strong Ab 97 c Mk SiCL 10Y 3/1 0 ma vs >1 Strong Cgb1 150 g SiCL 10Y 3/1 0 ma vs >1 Strong Cgb2 198 a SiCL 10Y 4/0.5 0 ma vs >1 Strong Oab 218 - Mk 10YR 2/2 Strong Remarks: Profile description by D.M. Balduff, 9 June 2005 at 11:28 am. Sampled using a vibracorer; depth inside core 192 cm, depth outside core 172 cm. Worm tubes on surface. 343 Sample CB33 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Aeric Sulfiwassents) 38? 07? 01.8? N, 75? 17? 28.7? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL 5Y 4/1 0 ma ns < 0.7 None A2 25 a SL N3 0 ma ns < 0.7 1 None Cg1 39 a SL 5Y 5/1 0 ma ns < 0.7 None Cg2 58 c SL 5Y 5/2 0 ma ns < 0.7 None Cg3 119 - SL 5Y 5/2 0 ma ns < 0.7 None Remarks: Profile description by D.M. Balduff, 10 June 2005 at 8:05 am. Sampled using a vibracorer; depth inside core 185 cm, depth outside core 175 cm. 344 Sample CB34 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 06? 57.7? N, 75? 17? 27.1? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a L 5Y 4/1 0 ma 0.7-1 Strong A2 23 c SiC 10Y 2.5/1 0 ma >1 Strong Cg1 55 c SiC 10Y 3/1 15 10Y 7/6 0 ma >1 Strong Ab 99 c Mk SiC 10Y 3.5/1 45 10YR 3/3 0 ma >1 Strong Cgb1 114 c SiC 10Y 3/1 7 10YR 3/3 0 ma >>1 Strong Cgb2 157 c SiC 10Y 3/1 20 10YR 3/3 0 ma >>1 Strong Cgb3 200 - SiC 10Y 3.5/1 10 10YR 6/6 0 ma >1 Strong Remarks: Profile description by D.M. Balduff, 10 June 2005 at 10:15 am. Sampled using a McCauley sampler. 345 Sample CB35 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 01.5? N, 75? 17? 46.8? W Water Depth 87 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 LfS 5Y 4/2 0 ma vs >>1 Strong A2 16 fSL N3 0 ma ss 0.7-1 Strong 2Cg1 30 SiCL/SiC 10Y 3/1 0 ma vs >1 Strong 2Cg2 72 SiCL/SiC 5GY 3/1 0 ma vs >1 25 Strong 2Cg3 99 SiCL/SiC 10Y 3.5/1 0 ma vs >1 10 Strong 2Cg4 125 SiCL/SiC 10Y 3.5/1 0 ma vs >1 10 Strong 2Cg5 162 SiCL/SiC 10Y 3.5/1 2 5Y 5/6 0 ma vs >1 15 Strong Remarks: Profile description by D.M. Balduff, 23 June 2005 at 8:13 am. Sampled using a vibracorer; depth inside core 145 cm, depth outside core 97 cm. Oyster and gastropod shells in 2Cg3 and 2Cg4. 346 Sample CB36 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 05? 50.3? N, 75? 18? 43.4? W Water Depth 109 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 1 SiCL 5Y 4/2 0 ma vs >>1 Strong A2 38 SiCL 10Y 3/1 1 2.5Y 3/3 0 ma vs >1 Weak 2Cg1 62 SL 10Y 4/1 0 ma ss < 0.7 Strong 2Cg2 89 LS 10Y 4.5/1 0 sg ss < 0.7 Strong Remarks: Profile description by D.M. Balduff, 23 June 2005 at 10:03 am. Sampled using a McCauley Sampler. 347 Sample CB37 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 37.3? N, 75? 19? 20.8? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/2 0 ma vs >>1 Strong Cg1 114 g SiC 5GY 3/1 0 ma vs >1 1 Strong Cg2 152 g SiC 10Y 4/1 10 2.5Y 3/3 0 ma vs >1 2 Strong Cg3 199 - SiC 10Y 4/1 0 ma vs >1 3 Strong Remarks: Profile description by D.M. Balduff, 23 June 2005 at 10:36 am. Sampled using a McCauley Sampler. 348 Sample CB38 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 21.2? N, 75? 19? 46.0? W Water Depth 135 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 6 SiC 5Y 4/1 0 ma ms >>1 Strong Cg1 54 SiC 10Y 3/1 0 ma ms >1 1 Strong Cg2 72 SiC 10Y 3/1 0 ma ms >1 10 Strong Cg3 162 SiC 10Y 3/1 0 ma ms >1 1 Strong Remarks: Profile description by D.M. Balduff, 23 June 2005 at 11:41 am. Sampled using a McCauley Sampler. 349 Sample CB39 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 05? 56.50? N, 75? 19? 59.20? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 1 SiC 5Y 4/2 0 ma ms >1 Weak A2 12 SiC SiCL 10Y 2.5/1 0 ma ms >1 1 None Cg1 43 SiC SiCL 10Y 3/1 0 ma ms >1 None Cg2 57 SiC SiC 5GY 3/1 0 ma ms >>1 None Cg3 126 SiC SiL 10Y 3/1 0 ma ms >1 None 2Cg4 161 LS fSL 10Y 3/1 0 sg ss <0.7 None 2Cg5 198 LS LfS 5Y 5/2 0 sg ss <0.7 None Remarks: Profile described by D. Balduff, 23 June 2005 at 12:22 pm Sampled using McCauley peat auger Worm tubes on surface 350 Sample CB40 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 07? 14.8? N, 75? 16? 1.0? W Water Depth 225 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 13 c SiC 5GY 3/1 0 ma ms >>1 Strong Cg1 50 c SiC 5GY 3/1 0 ma ms >1 2 Strong Cg2 83 g fSL 10Y 3/1 0 ma ss >1 Strong Cg3 120 c C 5GY 3/1 0 ma ms >1 Strong Cg4 130 c SiC 5GY 3/1 0 ma ss >>1 Strong Cg5 152 - SiC 10Y 3/1 0 ma ms >1 1 Strong Remarks: Profile description by D.M. Balduff, 24 June 2005 at 9:09 am. Sampled using a McCauley Sampler. 351 Sample CB41 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 06? 07.20? N, 75? 19? 00.40? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a L - 5Y 3.5/1 0 ma Strong A2 17 c L fSL 10Y 2.5/1 0 ma 0.7-1 1 Strong 2Cg1 52 c fSL CL 10Y3/1 0 ma >1 15 Strong 2Cg2 143 - SiC CL 5GY 3.5/1 0 ma >1 None Remarks: Profile described by D. Balduff, 24 June 2005 at 20:49 am Sampled using McCauley peat sampler, stopped at 143 cm Worm tubes on surface 352 Sample CB42 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 06? 6.0? N, 75? 19? 4.5? W Water Depth 107 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiC 5Y 4/2 0 ma ms >1 Strong A2 29 c SiC 10Y 3/1 0 ma ms >1 Strong Cg1 46 g SiC 5GY 4/1 3 2.5Y 3/3 0 ma ms >1 Strong Cg2 83 c SiC 10Y 3/1 5 2.5Y 3/3 0 ma ss >1 Strong Ab 95 c Mk SiC 2.5Y 3/2 45 2.5Y 5/6 0 ma ss >1 Strong Cgb1 138 g Mk SiC 10Y 3/1 30 2.5Y 5/6 0 ma ss >1 Strong Cgb2 172 g SiC 5GY 3.5/1 3 2.5Y 6/6 0 ma ms >1 Strong Cgb3 199 - SiC 5GY 3.5/1 0 ma ms >1 1 Strong Remarks: Profile description by D.M. Balduff, 24 June 2005 at 11:30 am. Sampled using a McCauley Sampler. Worm tubes on surface. Gastropod shell in Cgb3 353 Sample CB43 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 4.9? N, 75? 18? 40.0? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiC 5Y 4/1 0 ma ms >>1 Strong A2 16 c SiC N3 0 ma ms >>1 trace Strong Cg1 32 g SiC 10Y 3/1 20 10YR 3/3 0 ma ms >1 Strong Cg2 123 g SiC 10Y 3/1 20 5Y 5/4 0 ma ms >1 Strong Cg3 199 - SiC 10Y 3/1 3 5Y 5/4 0 ma ms >1 Strong Remarks: Profile description by D.M. Balduff, 24 June 2005 at 12:44 pm. Sampled using a McCauley Sampler. Worm tubes on surface. 354 Sample CB44 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 05? 30.1? N, 75? 15? 8.6? W Water Depth 90 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 6 a Sl N 2.5 0 ma >1 15 Strong A2 18 c SL 10Y 3/1 0 ma 0.7-1 1 Strong Cg1 43 c SL 10Y 3.5/1 0 ma <0.7 Strong Cg2 67 c L 10Y 3.5/1 0 ma 0.7-1 Strong Cg3 85 c SL 10Y 3.5/1 0 ma 0.7-1 2 Strong 2Cg4 104 c LS N 4 0 sg <0.7 Strong 2Cg5 137 - SL N 4 0 sg <0.7 1 Strong Remarks: Profile description by D.M. Balduff, 28 June 2005 at 8:50 am. Sampled using a vibracorer; depth inside core 129 cm, depth outside core 111 cm. Eelgrass on surface. 355 Sample CB45 Sandy over loamy, Haplic Sulfaquents (Sandy over loamy, Haplic Sulfiwassents) 38? 04? 59.1? N, 75? 13? 53.7? W Water Depth 90 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist . Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 6 c S fS 5Y 4/1 N3 25% 0 sg ns <0.7 15 Strong A/Cg 33 c S fS N4 N3 20% 0 sg ns <0.7 Strong Cg1 88 c LS fS N 3.5 0 sg ns <0.7 Strong Cg2 99 c LS/SL LfS 10Y 3.5/1 0 ma ss <0.7 Strong 2Cg3 142 a SiC L 10Y 3/1 15 5Y 5/6 0 ma ms >1 Strong 2Cg4 186 - SiC SiCL 10Y 3/1 20 5Y 5/6 0 ma ss 0.7-1 1 Strong Remarks: Profile description by D.M. Balduff, 28 June 2005 at 1:46 pm. Sampled using a vibracorer; depth inside core 120 cm, depth outside core 113 cm. Eelgrass on surface. 356 Sample CB46 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 37.3? N, 75? 19? 20.8? W Water Depth 90 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 5 a L 5Y 4/1 0 ma ss >>1 Weak Cg1 19 c L 10Y 3/1 0 ma ms >1 1 Weak Cg2 40 c SiC 5GY 3/1 0 ma ms >1 Weak Cg3 82 c SiC 10Y 3/1 0 ma ms >1 Weak Cg4 126 a SiC 10Y 3.5/1 0 ma ms >1 2 Weak Cg5 160 - SiC 10Y 4/1 0 ma ss >1 10 Weak Remarks: Profile description by D.M. Balduff, 30 June 2005 at 9:22 am. Sampled using a McCauley sampler. 357 Sample CB47 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 59.7? N, 75? 19? 0.4? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 5 a SiC 5Y 4/1 0 ma ss >>1 Strong A2 18 c SiC 10Y 2.5/1 0 ma ms >1 2 Strong A/Cg 31 c SiC 10Y 3/1 0 ma ss >1 Strong Cg1 111 g SiC 10Y 3/1 0 ma ss >1 Strong Cg2 148 - SiC 10Y 3/1 0 ma ss >1 Strong Remarks: Profile description by D.M. Balduff, 30 June 2005 at 11:20 am. Sampled using a McCauley sampler. 358 Sample CB48 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 57.3? N, 75? 18? 48.0? W Water Depth 140 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 3 c C 10Y 2.5/1 0 ma ss 0.7-1 1 Strong Cg1 23 c C 10Y 3/1 0 ma ss 0.7-1 3 Strong Cg2 44 g SiC 10Y 3/1 0 ma ss >1 Trace Strong Cg3 103 g SiC 10Y 3/1 0 ma ms >>1 Trace Strong Cg4 254 - SiC 10Y 3/1 0 ma ms >1 1 Strong Remarks: Profile description by D.M. Balduff, 30 June 2005 at 12:17 pm. Sampled using a McCauley sampler. 359 Sample CB49 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents) 38? 06? 52.2? N, 75? 15? 47.9? W Water Depth 280 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist . Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SiC 10Y 3/1 0 ma ms >>1 Strong A2 10 c L L 10Y 4/1 0 ma ms >1 Strong Cg1 42 c C SL 10Y 3/1 0 ma ms >1 1 Strong Cg2 80 c CL fSL 10Y 3/1 0 ma ms >1 5 Strong Ab 105 a L 10Y 3/1 0 ma ns 0.7-1 10 Strong Cgb1 131 a SiC 10Y 3.5/1 0 ma ss >1 25 Strong Cgb2 147 - SiC 10Y 3.5/1 0 ma ms >1 Strong Remarks: Profile description by D.M. Balduff, 1 July 2005 at 8:37 am. Sampled using a vibracorer; depth inside core 260 cm, depth outside core 253 cm. 360 Sample CB50 Coarse-silty, Sulfic Hydraquents (Coarse-silty, Sulfic Hydrowassents) 38? 05? 41.2? N, 75? 16? 44.8? W Water Depth 250 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist . Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiC 5Y 4/1 0 ma ss >>1 10 Weak A2 21 a C SL N 3 0 ma ss 60 Weak A/Cg 45 c C L 10Y 3/1 0 ma ss 40 Weak Cg1 60 c C L 10Y 3.5/1 0 ma ms >1 7 Weak Cg2 92 g C L 5GY 3/1 0 ma ss 0.7-1 15 Strong Cg3 160 - C vfSL 5GY 3/1 0 ma ss 0.7-1 7 Strong Remarks: Profile description by D.M. Balduff, 1 July 2005 at 10:29 am. Sampled using a vibracorer; depth inside core 240 cm, depth outside core 220 cm. Whole mussel at 35 cm, Clam at 84 cm, Oyster at 33 cm, Gastropods throughout. 361 Sample CB51 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 04? 25.5? N, 75? 19? 34.3? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist . Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 5 a LS 5Y 4/1 0 sg ns < 0.7 None A2 25 c LS 10Y 4.5/1 N 2.5 (30) 0 sg ns < 0.7 3 None Cg1 36 c LS 5GY 3/1 0 sg ns < 0.7 3 None 2Ab 56 c Mk L 5GY 3/1 40 10YR 3/2 0 ma ms 0.7-1 None 2Cgb 1 65 c SL 5GY 3.5/1 10 5Y 5/4 0 ma ss 0.7-1 None 2Cgb 2 83 c SL N 4 10 5Y 5/4 0 ma ns < 0.7 None 2Cgb 3 102 - SL N 5 0 ma ns < 0.7 None Remarks: Profile description by D.M. Balduff, 1 July 2005 at 12:48 pm. Sampled using a vibracorer; depth inside core 95 cm, depth outside core 90 cm. Worm tubes on surface. 362 Sample CB52 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 05? 4.1? N, 75? 13? 53.3? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 5 a SL SL 5Y 4/1 0 ma ss >>1 Strong A2 10 a Sl SL N 2.5 0 ma ns >1 Strong Cg1 21 c Sl/L L 10Y 2.5/1 0 ma ns < 0.7 3 Strong 2Cg2 39 c SiC L 10Y 3/1 0 ma ss >1 1 Strong 2Cg3 59 g SiC L 10Y 3/1 0 ma ms >1 Strong 2Cg4 86 c SiC CL 10Y 3.5/1 0 ma ss >1 2 Strong 2Cg5 115 c SiC L 10Y 3/1 0 ma ms >1 2 Strong 2Cg6 138 - L SL 10Y 3.5/1 0 ma ss 0.7-1 Strong Remarks: Profile described by D. Balduff, 5 July 2005 at 10:45 am Sampled using McCauley peat auger. 363 Sample CB53 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 9.0? N, 75? 14? 41.8? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 6 c Sl 5Y 4/1 0 ma ss >>1 Strong Cg1 22 c Sl 10Y 3/1 0 ma ns < 0.7 Strong 2Cg2 48 g SiC 10Y 3/1 0 ma ms >1 Strong 2Cg3 113 g SiC 10Y 3/1 0 ma ms >1 3 Strong 2Cg4 178 c SiC 10Y 3.5/1 0 ma ms >1 Strong 2Cg5 184 - L 10Y 3.5/1 0 ma ss 0.7-1 1 Remarks: Profile description by D.M. Balduff, 5 July 2005 at 12:00 pm. Sampled using a McCauley sampler. Worm tubes on surface. 364 Sample CB54 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 04? 57.7? N, 75? 15? 17.1? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 12 a Sl 5Y 4/1 0 ma ns < 0.7 1 None A2 23 a LS N 2.5 0 sg ns < 0.7 4 None Cg1 42 c LS 10Y 3/1 0 sg ns < 0.7 5 None Cg2 67 c S N 4.5 3 5Y 3/2 0 sg ns < 0.7 2 None Cg3 101 c S N 4.5 0 sg ns < 0.7 1 None Cg4 132 c S N 5 0 sg ns < 0.7 1 None Cg5 165 a S 10Y 5/1 0 sg ns < 0.7 2 Weak 2Cg6 195 - L 5GY 4/1 0 ma ns 0.7-1 1 None Remarks: Profile description by D.M. Balduff, 5 July 2005 at 12:00 pm. Sampled using a Vibracorer, depth inside core 178 cm, depth outside core 172 cm. 365 Sample CB55 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 04? 50.40? N, 75? 15? 52.40? W Water Depth 185 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL fS 5Y 4/1 0 ma ns <0.7 Strong A2 12 a SL fS N 3 0 ma ns <0.7 5 Strong Cg1 41 c SL LfS 10Y 3.5/1 0 ma ss <0.7 3 Strong Cg2 90 g SL LfS 5GY 3.5/1 3 2.5Y 3/3 0 ma ss 0.7-1 1 Strong 2Cg3 143 g C L 5GY 3/1 0 ma ms >1 1 Strong 2Cg4 162 c L SL 10Y 3/1 4 5Y 4/4 0 ma ss 0.7-1 1 Strong 2Cg5 198 - SiC L 10Y 3/1 7 5Y 4/4 0 ma ms >1 1 Strong Remarks: Profile described by D. Balduff, 6 July 2005 at 8:15 am. Sampled using Vibracorer, depth inside core 170 cm, depth outside core 165 cm. Worm tubes on surface. 366 Sample CB56 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 04? 21.8? N, 75? 15? 34.1? W Water Depth 95 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a LS 5Y 4/1 N2.5 (25) 0 sg ns < 0.7 15 Strong A2 10 a LS fS N3 5 10YR 3/2 0 sg ns < 0.7 Strong Cg1 31 c S fS N4 0 sg ns < 0.7 Strong Cg2 49 c S fS N4.5 0 sg ns < 0.7 5 Strong Cg3 72 c Sl LfS 10Y 3/1 3 10YR 3/2 0 ma ns < 0.7 3 Strong Cg4 90 g LS fS 10Y 3/1 0 sg ns < 0.7 Strong Cg5 122 g LS fS 10Y 3/1 0 sg ns < 0.7 Strong Cg6 137 a LS fS 10Y 3/1 0 sg ns < 0.7 2 Strong 2Ab 154 - SiC LfS 5GY 3.5/1 30 10YR 4/6 2.5Y 5/6 0 ma ms >1 Strong Remarks: Profile described by D. Balduff, 6 July 2005 at 9:35 am. Sampled using Vibracorer, depth inside core 78 cm, depth outside core 70 cm. Eelgrass and worm tubes on surface. 367 Sample CB57 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 04? 16.1? N, 75? 14? 54.3? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 c SL 10Y 2.5/1 0 ma ns < 0.7 10 10 Strong A2 18 c SL 10Y 3/1 2 10YR 3/2 0 ma ns < 0.7 10 Strong Cg1 33 g LS 5GY 3/1 0 sg ns < 0.7 3 Strong Cg2 58 c LS 5GY 3/1 0 sg ns < 0.7 2 Strong Cg3 83 g S 5GY 3.5/1 0 sg ns < 0.7 1 Strong Cg4 111 a SL 5GY 3/1 1 10YR 3/3 0 ma ns < 0.7 Strong 2Cg5 130 - C 5GY 3.5/1 5 10YR 5/4 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff, 23 June 2005 at 11:15 am. Sampled using a vibracorer; depth inside core 80 cm, depth outside core 72 cm. A1- 0.5 cm thick 5Y 3/1. A2 and Cg3- oyster shells. 368 Sample CB58 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents) 38? 04? 44.5? N, 75? 16? 27.4? W Water Depth 240 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Ab un. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL - 5Y 4/1 0 ma ms >>1 Strong A2 14 a L LfS N 3 0 ma ss >1 2 Strong Cg1 37 c L fSL 10Y 3/1 0 ma ms 0.7-1 10 Strong Cg2 106 c SL fSL N 3.5 3 10YR 5/6 0 ma ss 0.7-1 2 Strong 2Cg3 162 - SiC SiCL 10Y 3.5/1 5 10YR 5/6 0 ma ms >1 Strong Remarks: Profile described by D. Balduff, 6 July 2005 at 12:56 pm. Sampled using Vibracorer, depth inside core 235 cm, depth outside core 225 cm. 369 Sample CB59 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 27.0? N, 75? 15? 5.1? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 5 a SiL 5Y 4/2 0 ma ss > 1 Strong A2 29 a SiL 10Y 2.5/1 0 ma ss > 1 Strong Cg1 35 c Mk SiCL 10Y 3/1 0 ma ss > 1 Strong Cg2 74 c Mk SiCL 10Y 3.5/1 40 2.5Y 6/6 0 ma ss > 1 Strong Cg3 86 c SiC 10Y 3/1 25 2.5Y 4/6 0 ma ms > 1 Strong Cg4 127 a SiC 10Y 3/1 10 2.5Y 6/6 0 ma ms > 1 Strong 2Cg5 135 - SL N 3.5 3 2.5Y 5/6 0 ma ss 0.7-1 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 9:27 am. Sampled using a McCauley sampler. Worm tubes on surface. 370 Sample CB60 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 26.0? N, 75? 15? 21.8? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 7 a CL 5Y 4/2 3 10Y 3/2 0 ma ms > 1 Strong A2 11 a SiL N 3 0 ma ss > 1 Strong A3 40 a Mk SiC 10Y 3/1 30 5Y 6/6 0 ma ms > 1 Strong Cg1 49 c SiC 10Y 3/1 2 5Y 6/6 0 ma ms > 1 Strong Cg2 66 c L 5GY 3/1 2 5Y 6/6 0 ma ss 0.7-1 Strong Cg3 87 c SiC 10Y 3/1 25 5Y 6/6 0 ma ms > 1 Strong Cg4 115 c C 10Y 3/1 5 5Y 6/6 0 ma ms > 1 Strong Cg5 149 c C 10Y 3/1 0 ma ms > 1 Strong Cg6 165 a SiC 10Y 3/1 0 ma ms > 1 Strong 2Cg7 203 - SL 10Y 3/1 0 ma ms 0.7-1 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 10:02 am. Sampled using a McCauley sampler. 371 Sample CB61 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 31.5? N, 75? 15? 40.0? W Water Depth 178 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a L 5Y 4/2 0 ma ss 10 Strong A2 9 a L N 2.5 0 ma ss 60 Strong Cg1 62 g SiC 10Y 3/1 0 ma ms >1 Strong Cg2 123 g SiC 10Y 3/1 0 ma ms >1 10 Strong Cg3 152 - SiC 10Y 3/1 3 5Y 5/6 0 ma ms >1 3 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 10:42 am. Sampled using a McCauley sampler. Shells in A2 were broken. Identified clam, gastropod, and oyster shells. 372 Sample CB62 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 29.5? N, 75? 15? 56.9? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL 5Y 4/1 0 ma 15 Strong A2 10 a SL 10Y 2.5/1 0 ma 65 Strong Cg1 35 c L 10Y 3/1 0 ma ss 0.7-1 3 Strong 2Cg2 95 - SiC 10Y 3/1 0 ma ms > 1 20 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 11:23 am. Sampled using a McCauley sampler. Broken shells in A2. Bands of broken shells in 2Cg2 45-47 cm and 64-65 cm. Identified oyster and gastropod shells. Could not sample deeper than 95 cm with McCauley sampler. 373 Sample CB63 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 46.0? N, 75? 16? 50.6? W Water Depth 300 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiC 5Y 4/1 0 ma ms >> 1 None A2 38 c SiC 10Y 2.5/1 0 ma ms > 1 None Cg1 72 g SiC 10Y 3/1 0 ma ms > 1 5 Strong Cg2 172 - SiC 10Y 3/1 1 10YR 3/3 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 12:41 pm. Sampled using a McCauley sampler. 374 Sample CB64 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 01? 42.6? N, 75? 17? 16.1? W Water Depth 227 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/1 0 ma ms >> 1 Strong Cg1 22 c SiC 10Y 2.5/1 0 ma ms > 1 Strong Cg2 43 c SiC 10Y 3/1 3 10YR 5/6 0 ma ms > 1 2 Strong Cg3 82 c SiC 10Y 3/1 15 10YR 6/6 0 ma ms > 1 Strong Cg4 141 g SiC 10Y 3/1 7 10YR 6/6 0 ma ms > 1 Strong 2Cg5 150 c SL 10Y 3.5/1 0 ma ms 0.7-1 Strong 2Cg6 160 - L/SL 10Y 3.5/1 0 ma ss 0.7-1 3 Strong Remarks: Profile description by D.M. Balduff, 9 July 2005 at 1:23 pm. Sampled using a McCauley sampler. Oyster shell identified in 2Cg6. 375 Sample CB65 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 29.1? N, 75? 16? 17.0? W Water Depth 235 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 6 a SL 5Y 3/2 0 ma ss < 0.7 2 Strong A2 11 c SL N 3 0 ma ss < 0.7 30 Strong 2Cg1 29 c SiC 10Y 3/1 0 ma ms > 1 2 Strong 2Cg2 106 g SiC 10Y 3/1 0 ma ms > 1 10 Strong 2Cg3 155 - SiC 10Y 3/1 0 ma ms > 1 3 Strong Remarks: Profile description by D.M. Balduff, 10 July 2005 at 9:28 am. Sampled using Vibracorer, depth inside core 220 cm, depth outside core 220 cm. 376 Sample CB66 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 03? 28.2? N, 75? 16? 49.1? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 10 a LS 5Y 3/2 0 sg ns < 0.7 Weak A2 13 a SL N 3 0 ma ns < 0.7 3 Weak Cg/A 44 c SL 10Y 3/1 0 ma ns < 0.7 5 Weak 2Cg1 94 g L 10Y 3/1 0 ma ms 0.7-1 2 Strong 2Cg2 159 c C 10Y 3/1 0 ma ms > 1 2 Strong 2Cg3 168 - SiC 10Y 3/1 0 ma ms > 1 30 Strong Remarks: Profile description by D.M. Balduff, 10 July 2005 at 10:35 am. Sampled using Vibracorer, depth inside core 205 cm, depth outside core 200 cm. Krotovina in Cg/A- N 3/ soil material in channel. Broken shells in 2Cg3. Clam and mussel on surface. 377 Sample CB67 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 03? 22.6? N, 75? 17? 25.6? W Water Depth 235 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SL 5Y 4/2 0 ma ss >> 1 None A2 13 c SL N 2.5 0 ma ss 0.7-1 None Cg/A 35 c L 10Y 3/1 N 3 (10) 15 10YR 3/3 0 ma ms > 1 1 None 2Cg1 73 g SiC 10Y 3.5/1 25 10YR 4/4 0 ma ms > 1 1 Weak 2Cg2 135 c SiC 10Y 3/1 10 2.5Y 6/6 0 ma ms > 1 2 Weak 2Cg3 146 - C N 3.5 5 2.5Y 6/6 0 ma ms > 1 Weak Remarks: Profile description by D.M. Balduff, 10 July 2005 at 11:45 am. Sampled using a McCauley sampler. 378 Sample CB68 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 03? 28.5? N, 75? 17? 29.7? W Water Depth 50 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 2 a SL 5Y 3/1 0 ma 80 Strong Cg1 14 c 10Y 3/1 0 sg 90 Strong Cg2 35 c 10Y 3/1 0 sg 90 Strong Cg3 47 c LS 10Y 3.5/1 0 ma 40 Strong 2Cg4 68 c SiC 10Y 3.5/1 0 ma ms > 1 10 Strong 2Ab 97 - Mk SiC 10Y 3/1 20 5Y 6/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff, 11 July 2005 at 8:45 am. Sampled using Vibracorer, depth inside core 95 cm, depth outside core 115 cm. Cg1 contained small broken shells. Cg2 contained large broken shells. 379 Sample CB69 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 25.3? N, 75? 18? 3.9? W Water Depth 210 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SL 5Y 4/1 0 ma ss >> 1 Weak A2 22 c SL 10Y 3/1 N 3 (15) 0 ma ss 0.7-1 10 Weak 2Cg1 47 c SiC 10Y 3.5/1 0 ma ms > 1 3 Strong 2Cg2 77 c SiC 10Y 3/1 0 ma ss > 1 Strong 2Cg3 117 g SiC 10Y 3/1 15 5Y 5/6 0 ma ms > 1 Strong 2Cg4 152 - SiC 10Y 3/1 5 5Y 5/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff, 11 July 2005 at 9:41 am. Sampled using Vibracorer, depth inside core 220 cm, depth outside core 190 cm. 380 Sample CB70 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 25.4? N, 75? 18? 24.9? W Water Depth 210 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 5 a L 5Y 4/2 0 ma ss > 1 None A2 19 c SL 2.5Y2.5/1 N 3 (5) 0 ma ss 0.7-1 None 2Cg1 44 c SiC 10Y 3/1 N 3 (3) 0 ma ms > 1 2 None 2Cg2 78 c SiC 10Y 3/1 0 ma ms > 1 Weak 2Cg3 92 g SiC 10Y 3/1 10 5Y 5/8 0 ma vs > 1 Weak 2Cg4 127 c SiC 10Y 3/1 5 5Y 5/8 0 ma ms >> 1 Weak 2Cg5 141 - SiC 10Y 3/1 3 5Y 5/8 0 ma vs > 1 Weak Remarks: Profile description by D.M. Balduff, 11 July 2005 at 10:24 am. Sampled using a McCauley sampler. 381 Sample CB71 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 28.9? N, 75? 18? 49.5? W Water Depth 194 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A 4 a L 5Y 3/2 0 ma ss >> 1 Weak Cg1 34 c C 10Y 3/1 3 2.5Y 3/2 0 ma ms > 1 2 Weak Cg2 61 g SiC 10Y 3/1 10 5Y 6/6 0 ma ms > 1 3 Strong Cg3 135 g SiC 10Y 3/1 5 2.5Y 5/6 0 ma ms > 1 Strong Cg4 214 - SiC 5GY 3/1 2-Jan 2.5Y 3/2 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff, 11 July 2005 at 11:22 am. Sampled using a McCauley sampler. 382 Sample CB72 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 42.3? N, 75? 17? 0.4? W Water Depth 245 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SiC 5Y 4/1 0 ma ss >> 1 None A2 13 c SiC N 2.5 10Y 2.5/1 0 ma ms > 1 1 None Cg1 48 c SiC 10Y 3/1 0 ma ms > 1 None Cg2 69 g SiC 10Y 3.5/1 0 ma ms > 1 3 None Cg3 107 g SiC 10Y 3/1 0 ma ms > 1 None Cg4 131 g C 10Y 3/1 0 ma ms > 1 Weak Cg5 156 - SiC 10Y 3/1 0 ma ms > 1 Weak Remarks: Profile description by D.M. Balduff, 11 July 2005 at 12:20 pm. Sampled using a McCauley sampler. 383 Sample CB73 Coarse-loamy, Haplic Sulfaquents (Coarse-loamy, Haplic Sulfiwassents) 38? 05? 43.0? N, 75? 17? 26.1? W Water Depth 205 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SL 5Y 4/2 0 ma ss 0.7 - 1 None A2 18 a SL N 2.5 0 ma ss < 0.7 5 None Cg1 34 c L 10Y 3/1 1 5Y 6/4 0 ma ss 0.7 - 1 None Cg2 54 c SiC 10Y 4/1 10Y 3/1 (20) 3 5Y 6/4 0 ma ss 0.7 - 1 10 None Cg3 78 c L 10Y 4/1 10Y 5/1 (30) 15 5Y 6/4 0 ma ms 0.7 - 1 None Cg4 91 - SL 10Y 4/1 5Y 5/3 (20) 0 ma ms 0.7 - 1 None Remarks: Profile description by D.M. Balduff, 11 July 2005 at 12:46 pm. Sampled using a McCauley sampler. 384 Sample CB74 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 01? 52.8? N, 75? 16? 27.6? W Water Depth 60 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A1 2 a SL 5Y 3/2 0 ma ss 0.7 - 1 10 None A2 19 c SL SL 10Y 2.5/1 2 10YR 3/2 0 ma ss 0.7 - 1 10 None Cg1 55 c SL LfS 10Y 3/1 2 10YR 3/2 0 ma ns < 0.7 None Cg2 89 c SL LfS 10Y 3.5/1 2 10YR 3/2 0 ma ns 0.7 - 1 1 None Cg3 109 c LS LfS 10Y 3/1 5 10YR 3/2 0 ma ss 0.7 - 1 Weak 2Cg4 142 c LS LfS 10Y 3.5/1 0 sg ns < 0.7 3 Weak 2Cg5 174 - S fS N 4 0 sg ns < 0.7 None Remarks: Profile described by D. Balduff, 12 July 2005 at 9:12 am. Sampled using Vibracorer, depth inside core 64 cm, depth outside core 42 cm. 385 Sample CB75 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 02? 0.6? N, 75? 16? 46.3? W Water Depth 165 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 7 c cS N 3 5Y 4/1 (10) 0 sg ns < 0.7 2 None A2 26 c cS N3 10Y 3/1(25) 0 sg ns < 0.7 5 None Cg1 88 c SL 10Y 3/1 0 ma ns < 0.7 10 Weak Cg2 107 g LS 10Y 3/1 0 sg ns < 0.7 5 Weak Cg3 191 - S 10Y 4/1 0 sg ns < 0.7 1 Weak Remarks: Profile description by D.M. Balduff, 12 July 2005 at 10:45 am. Sampled using Vibracorer, depth inside core 173 cm, depth outside core 170 cm. 386 Sample CB76 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 02? 12.1? N, 75? 15? 14.6? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 6 c SL 5Y 3/1 0 ma ns 0.7 - 1 15 Weak A2 21 c SL 10Y 3/1 0 ma ns < 0.7 15 Strong Cg1 58 c SL 10Y 3/1 0 ma ns < 0.7 10 None Cg2 105 c S 10Y 3.5/1 0 sg ns < 0.7 1 Weak Cg3 151 c LS 10Y 3/1 2.5Y 3/2 0 sg ns < 0.7 1 None Cg4 169 - S 10Y 4/1 0 sg ns < 0.7 None Remarks: Profile description by D.M. Balduff, 12 July 2005 at 12:19 pm. Sampled using Vibracorer, depth inside core 65 cm, depth outside core 70 cm. Eelgrass on surface. Razor clam at 42 cm. Broken clam shells in Cg3. 387 Sample CB77 Sandy, Haplic Sulfaquents (Sulfic Psammowassents) 38? 02? 7.4? N, 75? 15? 51.4? W Water Depth 175 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 7 a LS 5Y 4/1 0 sg ns < 0.7 None A2 20 c LS N 3 0 sg ns < 0.7 2 None Cg1 33 c SL 10Y 3/1 0 ms ns < 0.7 None Cg2 49 c LS 10Y 3/1 0 sg ns < 0.7 None Cg3 72 a S N 4 0 sg ns < 0.7 2 None Cg4 124 c cS N 5 0 sg ns < 0.7 5 Weak Cg5 153 c cS N 4 10 10YR 3/2 0 sg ns < 0.7 2 Weak 2Cg6 178 c C 10Y 3/1 5 10YR 3/2 0 ma ms > 1 1 Strong 2Cg7 224 - SiC 10Y 3/1 3 10YR 3/2 0 ma ms > 1 1 Strong Remarks: Profile description by D.M. Balduff, 12 July 2005 at 1:33 pm. Sampled using Vibracorer, depth inside core 180 cm, depth outside core 175 cm. From 129-133 cm band of 10Y 3/1 with SL texture. 388 Sample CB78 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 01? 53.7? N, 75? 17? 8.6? W Water Depth 195 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Moist Const. n value Roots % Shells % Intensity of H 2 S A1 2 a S 5Y 4/1 0 sg ns < 0.7 None A2 17 c S N 3 0 sg ns < 0.7 1 None Cg1 50 c SL 10Y 3/1 2 2.5Y 3/3 0 ma ns 0.7 - 1 3 None Cg2 162 c S N 4 0 sg ns < 0.7 Weak Cg3 209 - LS N 4 0 sg ns < 0.7 2 Weak Remarks: Profile description by D.M. Balduff, 13 July 2005 at 9:04 am. Sampled using Vibracorer, depth inside core 187 cm, depth outside core 177 cm. 389 Sample CB79 Sandy, Haplic Sulfaquents (Sandy, Haplic Sulfiwassents) 38? 01? 54.4? N, 75? 17? 45.0? W Water Depth 235 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A1 3 a S 5Y 4/1 0 sg ns < 0.7 2 None A2 10 a S fS N 2.5 0 sg ns < 0.7 15 None Cg1 50 c SL fSL 10Y 3/1 0 ma ss 0.7 - 1 3 Strong Cg2 86 c SL LfS 5GY 3.5/1 0 ma ss 0.7 - 1 2 Strong Cg3 123 - S fS N 4 0 sg ns < 0.7 Strong Remarks: Profile described by D. Balduff, 13 July 2005 at 9:55 am. Sampled using Vibracorer, depth inside core 210 cm, depth outside core 200 cm. 390 Sample CB80 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Aeric Sulfiwassents) 38? 03? 32.4? N, 75? 19? 41.1? W Water Depth 150 cm Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Abun. % Color Gr. Shape Moist Const . n value Shells % Intensity of H 2 S A1 8 a SL 5Y 4/1 0 ma ns >> 1 None A2 17 c L 10Y 3/1 0 ma ms 0.7 - 1 2 None Cg1 30 c L 10Y 3/1 0 ma ms 0.7 - 1 7 None Cg2 57 a L 5Y 4/1 15 10 10Y 5/1 2.5Y 4/1 10 10YR 3/3 0 ma ms 0.7 - 1 2 None 2Cg3 75 c SCL 5Y 5/1 15 5Y 5/4 7 2.5Y 3/2 0 ma ss < 0.7 None 2C1 102 c SL 5Y 4/2 20 2 4 5Y 4/4 10YR 3/6 N 4 7 2.5Y 3/2 0 ma ns < 0.7 None 2C2 116 - SL 2.5Y 4/3 5 3 10YR 4/6 N 4 0 ma ns < 0.7 None Remarks: Profile description by D.M. Balduff; 13 July 2005 at 11:20 am Sampled using a vibracorer; depth inside core 125 cm, depth outside core 115 cm. Live razor clam in A2 during sampling. 391 Sample CB81 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 45.7? N, 75? 20? 1.8? W Water Depth 170 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A1 2 a SiC 5Y 4/1 0 ma ss >> 1 Weak A2 18 c SiC 10Y 3/1 0 ma ms >> 1 Weak Cg1 154 g SiC 10Y 3.5/1 0 ma ms > 1 3 Weak Cg2 213 - SiC 10Y 3.5/1 5 2.5Y 4/4 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 18 July 2005 at 10:57 am. Sampled using a McCauley sampler. Wormtubes on the surface. 392 Sample CB82 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 55.5? N, 75? 20? 27.6? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A 5 a SiC 5Y 4/1 0 ma ns >> 1 None Cg1 35 c SiC 10Y 3/1 0 ma ss > 1 Weak Cg2 60 g SiC 10Y 3/1 N 3 (20) 0 ma ss > 1 5 Weak Cg3 158 g SiC 10Y 3.5/1 0 ma ss > 1 Strong Cg4 196 - SiC 10Y 3/1 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 18 July 2005 at 11:37 am. Sampled using a McCauley sampler. Worm tubes on the surface. Cg1 has pockets of 3% 5Y 4/3 associated with worm tubes. 393 Sample CB83 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 12.8? N, 75? 20? 46.7? W Water Depth 145 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A1 2 a SiC 5Y 3/1 0 ma ss >> 1 Weak A2 16 c SiC 10Y 3/1 0 ma ss > 1 1 Weak Cg1 36 c SiC 10Y 3.5/1 0 ma ss > 1 20 Strong Cg2 130 c SiC 10Y 3.5/1 0 ma ss > 1 1 Strong Cg3 143 - SiC 10Y 3.5/1 0 ma ss > 1 15 Strong Remarks: Profile description by D.M. Balduff; 18 July 2005 at 12:17 pm. Sampled using a McCauley sampler. Worm tubes on surface. A2 contains 3% pockets of 5Y 4/3. 394 Sample CB84 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 32.2? N, 75? 21? 9.1? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A 6 c SiC 5Y 4/1 0 ma ns > 1 None Cg1 72 c SiC 10Y 3/1 0 ma ss > 1 7 None Cg2 138 c SiC 10Y 3/1 0 ma ss > 1 Strong Cg3 157 a Mk SiC 10Y 3/1 15 10YR 4/4 0 ma ms > 1 Strong Oab 166 c Mk 5Y 3/2 45 10YR 4/4 Strong Cgb1 176 c SiC 5Y 4/2 10 10YR 4/4 0 ma ss > 1 Strong 2Cgb2 216 - SL 5Y 4/2 10 10YR 4/4 0 ma ss 0.7 - 1 Strong Remarks: Profile description by D.M. Balduff; 18 July 2005 at 12:41 pm. Sampled using a McCauley sampler. Worm tubes on surface. 395 Sample CB85 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 04? 42.3? N, 75? 21? 21.7? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A1 5 a SiC 5Y 4/1 0 ma ms >> 1 None A2 21 c SiC 10Y 2.5/1 N 3 (2) 0 ma ms > 1 3 None Cg1 33 c C CL 10Y 3/1 0 ma ms > 1 None Cg2 57 c C CL 10Y 3/1 0 ma ms > 1 2 None 2Cg3 92 c SL SL 10Y 4/1 10Y 5/1 (10) 10Y 3/1 (5) 0 ma ss 0.7 - 1 None 2Cg4 120 c SL LfS 10Y 6/1 3 5Y 5/4 0 ma ns < 0.7 None 2Cg5 139 - SL 10Y 6/1 0 ma ns < 0.7 None Remarks: Profile described by D. Balduff, 19 July 2005 at 8:17 am. Sampled using Vibracorer, depth inside core 105 cm, depth outside core 90 cm. 396 Sample CB86 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 0.3? N, 75? 21? 26.0? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 3/1 0 ma ms > 1 5 None Cg1 35 c SiC 10Y 3/1 0 ma ms > 1 None Cg2 93 c SiC 5GY 3.5/1 0 ma ms > 1 None Oab 105 c Mk 10YR 2/1 30 5Y 6/6 None Cgb 138 - L 10Y 2.5/1 0 ma ss > 1 None Remarks: Profile description by D.M. Balduff; 19 July 2005 at 10:00 am. Sampled using a McCauley sampler. 397 Sample CB87 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 55.0? N, 75? 20? 40.2? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SiC 5Y 4/1 0 ma ss >> 1 None Cg1 47 c SiC 10Y 3/1 0 ma vs > 1 Weak Cg2 164 g SiC 10Y 3/1 0 ma ms > 1 2 Strong Cg3 240 - SiC 10Y 3/1 0 ma ms > 1 3 Strong Remarks: Profile description by D.M. Balduff; 19 July 2005 at 10:45 am. Sampled using a McCauley sampler. 398 Sample CB88 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 6.8? N, 75? 21? 21.9? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiC 5Y 4/1 0 ma ss >> 1 None A2 21 c SiC 10Y 3/1 0 ma vs > 1 None Cg1 115 g SiC 10Y 3.5/1 0 ma ms > 1 Strong Cg2 200 - SiC 10Y 3.5/1 0 ma ms > 1 3 Strong Remarks: Profile description by D.M. Balduff; 19 July 2005 at 11:20 am. Sampled using a McCauley sampler. Gastropod and oyster shells in Cg2. 399 Sample CB89 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 46.2? N, 75? 20? 58.1? W Water Depth 130 cm Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Abun. % Color Gr. Shape Moist Const . n value Shells % Intensity of H 2 S A1 2 a SiC 5Y 4/1 0 ma ss > 1 None A2 21 c SiC 10Y 3/1 1 10YR 4/4 0 ma ms > 1 None Cg1 88 c SiC 10Y 3/1 20 5Y 6/6 0 ma ms > 1 Strong Cg2 184 - SiC 10Y 3.5/1 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 19 July 2005 at 12:00 pm. Sampled using a McCauley sampler. 400 Sample CB90 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 03? 14.6? N, 75? 21? 4.0? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SiC 5Y 4/2 0 ma ns >> 1 Strong Cg1 32 c SiC 10Y 2.5/1 3 2.5Y 3/3 0 ma vs > 1 Strong Cg2 42 a SiC 10Y 3/1 5 2.5Y 4/3 0 ma ms > 1 Strong Cg3 72 c SiC 10Y 3/1 N 3 (15) 5 5Y 5/3 2.5Y 3/3 0 ma ns >>> 1 10 Strong Cg4 95 c SiC 10Y 3/1 3 5Y 6/6 0 ma ms > 1 Strong Cg5 114 c SiC 10Y 3.5/1 2 5Y 5/6 0 ma ss > 1 10 Strong 2Cg6 165 - SL 10Y 3/1 1 5Y 5/6 0 ma ms > 1 1 Strong Remarks: Profile description by D.M. Balduff; 19 July 2005 at 12:45 pm. Sampled using a McCauley sampler. 401 Sample CB91 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 03? 27.0? N, 75? 20? 8.4? W Water Depth 165 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Root s % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/2 0 ma ns >> 1 Weak Cg1 54 c SiC L 10Y 3/1 0 ma vs > 1 Weak 2Cg2 61 c SL SL 10Y 4/1 0 ma ns 0.7 - 1 Weak 3Cg3 139 g SiC SiCL 10Y 3/1 0 ma ms > 1 Weak 3Cg4 169 c SiC L 10Y 3/1 0 ma ms > 1 3 Weak 4Cg5 191 - SL SL 10Y 3.5/1 0 ma ss 0.7 - 1 10 Weak Remarks: Profile described by D. Balduff, 20 July 2005 at 8:28 am. Sampled using a McCauley sampler. Worm tubes on surface. 402 Sample CB92 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 2.5? N, 75? 19? 28.8? W Water Depth 170 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/1 0 ma ns >> 1 Strong Cg1 37 c SiC 10Y 3/1 0 ma ms > 1 Strong Cg2 94 c SiC 10Y 3/1 2 5Y 5/6 0 ma ms > 1 10 Strong Cg3 161 - SiC 10Y 3/1 5 5Y 5/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 20 July 2005 at 9:24 am. Sampled using a McCauley sampler. 403 Sample CB93 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 52.30? N, 75? 19? 26.90? W Water Depth 190 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiC SiL 5Y 4/1 0 ma ns >>1 None A2 15 c SiC SiL 10Y 2.5/1 0 ma vs >1 2 Weak Cg1 42 c SiC SiL 10Y 3/1 0 ma ms >1 Strong Cg2 81 g SiC SiCL 10Y 3/1 3 5Y 4/4 0 ma ms >1 2 Strong Cg3 210 - SiC SiCL 10Y 3.5/1 0 ma vs >1 Strong Remarks: Profile described by D. Balduff, 20 July 2005 at 10:00 am Sampled using McCauley peat sampler 404 Sample CB94 Fine, Typic Sulfaquents (Fine, Fluvic Sulfiwassents) 38? 02? 51.4? N, 75? 19? 51.8? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 1 a S 5Y 5/2 0 ma ns < 0.7 None A2 12 c S fS N3 10Y 4/1 0 ma ns < 0.7 2 Weak 2Cg1 33 c SiC SiC 10Y 3/1 3 5Y 6/6 0 ma ms > 1 1 Strong 2Cg2 94 c SiC SiC 5GY 3/1 10 5Y 6/6 0 ma ms > 1 Strong 2Cg3 107 c SiC SiC 10Y 3/1 0 ma ms > 1 10 Strong 2Cg4 145 - SiC SiC 10Y 3/1 7 5Y 6/6 0 ma ss >> 1 Remarks: Profile described by D. Balduff, 20 July 2005 at 11:14 am Sampled using Vibracorer, depth inside core 80 cm, depth outside core 75 cm. 2Cg4 had a ?jelly? consistence. 405 Sample CB95 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 48.1? N, 75? 19? 3.4? W Water Depth 210 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/1 0 ma ns >> 1 None Cg1 31 c SiC 10Y 2.5/1 0 ma ms > 1 Weak Cg2 48 c SiC 10Y 3/1 0 ma ss > 1 15 Strong Cg3 74 c SiC 10Y 3/1 0 ma ss >> 1 Strong Cg4 101 c SiC 10Y 3/1 0 ma ss > 1 2 Strong Cg5 180 - SiC 10Y 3.5/1 5 10YR 5/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 20 July 2005 at 12:33 pm. Sampled using a McCauley sampler. Cg3 had a ?soupy? consistence. 406 Sample CB96 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 48.3? N, 75? 18? 57.0? W Water Depth 235 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 10 c SiC 5Y 4/1 0 ma ns > 1 Strong Cg1 40 c SiC 10Y 3/1 0 ma ms > 1 2 Strong Cg2 81 c SiC 10Y 3/1 0 ma ms > 1 Strong Cg3 127 c SiC 10Y 3.5/1 0 ma ms > 1 10 Strong Cg4 158 c SiC 5GY 4/1 20 10YR 3/2 0 ma ms > 1 Strong Oa/Cg 188 - Mk SiC 2.5Y 4/1 40 10YR 3/2 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 20 July 2005 at 1:04 pm. Sampled using a McCauley sampler. 407 Sample CB97 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 08? 35.9? N, 75? 16? 30.0? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SiC 5Y 3/1 0 ma ns > 1 Strong Cg1 76 c SiC SiL 10Y 3/1 0 ma ms > 1 Strong Cg2 95 c C L 10Y 3/1 0 ma ms > 1 Strong Cg3 131 c SiC SiCL 10Y 3/1 0 ma ms > 1 3 Strong Cg4 145 c SiC SiCL 10Y 3/1 2 2.5Y 5/6 0 ma ms > 1 Strong Cg5 168 c SiC SiC 5Y 3/2 10Y 3.5/1 15 2.5Y 5/6 0 ma ss > 1 2 Strong Oa/Cg 195 a Mk SiCL 5Y 4/1 15 2.5Y 5/6 0 ma ss > 1 Strong Oab1 213 c Mk 5Y 3/2 40 2.5Y 5/6 Strong Oab2 224 c Mk 10YR 2/1 Strong Ab 245 c Mk L L 10YR 2/1 0 ma ss 0.7 - 1 Strong Cgb1 260 c SL L 5GY 4/1 0 ma ms 0.7 - 1 None Cgb2 266 - SL SL 5GY 4/1 5Y 4/2 (5) 0 ma ss 0.7 - 1 None Remarks: Profile description by D.M. Balduff; 21 July 2005 at 8:12 am. Sampled using a McCauley sampler. 408 Sample CB98 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 08? 46.5? N, 75? 16? 52.6? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SiC 5Y 4/1 0 ma ns >> 1 None Cg1 63 c SiC 10Y 2.5/1 0 ma ss > 1 Weak Cg2 128 c SiC 10Y 3/1 0 ma ms > 1 2 Strong Cg3 212 - SiC 10Y 3/1 5 10YR 3/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 21 July 2005 at 8:57 am. Sampled using a McCauley sampler. 409 Sample CB99 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 08? 30.3? N, 75? 15? 58.9? W Water Depth 250 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 5 a SiC 5Y 4/2 0 ma ss > 1 Strong A2 24 c SiC 10Y 2.5/1 0 ma ms > 1 Strong Cg1 51 c SiC 10Y 3/1 0 ma ms > 1 Strong Cg2 91 c SiC 10Y 3/1 2 2.5Y 3/2 0 ma ms > 1 10 Strong Oab1 101 c Mk 10YR 2/2 50 2.5Y 3/2 Strong Oab2 134 - Mk 10YR 3/2 50 2.5Y 6/6 Strong Remarks: Profile description by D.M. Balduff; 21 July 2005 at 9:27 am. Sampled using a McCauley sampler. 410 Sample CB100 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 08? 21.3? N, 75? 15? 19.1? W Water Depth 260 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiC 5Y 4/1 0 ma ns > 1 Strong Cg1 53 c SiC SiCL 10Y 2.5/1 0 ma ms > 1 Strong Cg2 80 c C L 10Y 3/1 0 ma ss > 1 Strong Cg3 100 g SiC SiCL 10Y 3/1 0 ma ms > 1 5 Strong Cg4 201 - SiC 10Y 3/1 0 ma ms > 1 Strong Remarks: Profile described by D. Balduff, 20 July 2005 at 10:20 am. Sampled using McCauley peat auger. Worm tubes on surface. 411 Sample CB101 Fine-silty, Thapto-histic Sulfaquents (Fine-silty, Thapto-histic Sulfiwassents) 38? 10? 20.0? N, 75? 15? 36.2? W Water Depth 210 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SiCL 5Y 4/1 0 ma ns > 1 None A2 12 c SiCL 10Y 2.5/1 0 ma ns > 1 2 None Cg1 52 c SiC 10Y 3/1 0 ma ms > 1 2 None Cg2 78 c SiC 10Y 3.5/1 0 ma vs > 1 None Oab1 93 c Mk 10YR 2/2 50 2.5Y 5/4 None Oab2 99 c Mk 10YR 2/1 50 2.5Y 5/4 None Ab 106 c SL 2.5Y 3/2 0 ma ns 0.7 - 1 None Cgb 115 - SL 2.5Y 4/1 0 ma ns 0.7 - 1 None Remarks: Profile description by D.M. Balduff; 21 July 2005 at 11:47 am. Sampled using a McCauley sampler. Worm tubes on surface. Oab1 contained 1 cm bands of 10Y 3.5/1 sediment layers. 412 Sample CB102 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 09? 20.2? N, 75? 14? 45.2? W Water Depth 240 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a C 10Y 3/1 0 ma ms > 1 None Cg1 51 c C 10Y 3/1 0 ma ms > 1 15 Strong Cg2 114 a SiC 10Y 3/1 0 ma ms > 1 Strong Oab 134 c Mk 2.5Y 2.5/1 50 10YR 5/6 Strong Ab 143 c Mk L 5Y 3/1 30 10YR 5/6 0 ma ms 0.7 - 1 Strong Cgb1 165 c SL 10Y 4/1 7 10YR 5/6 0 ma ss 0.7 - 1 Weak Cgb2 177 - SL 10Y 5/1 0 ma ss < 0.7 Weak Remarks: Profile description by D.M. Balduff; 21 July 2005 at 12:23 pm. Sampled using a McCauley sampler. Worm tubes on surface. 413 Sample CB103 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 06? 54.9? N, 75? 16? 27.1? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 4 a SiC 5Y 3/1 0 ma ss >> 1 Strong Cg1 70 c SiC 10Y 2.5/1 0 ma vs > 1 1 Strong Cg2 109 c C 10Y 3/1 0 ma ms > 1 3 Strong Cg3 117 - C 10Y 3/1 0 ma ms > 1 10 Strong Remarks: Profile description by D.M. Balduff; 22 July 2005 at 8:27 am. Sampled using a McCauley sampler. 414 Sample CB104 Fine-loamy, Haplic Sulfaquents (Fine-loamy, Haplic Sulfiwassents) 38? 11? 0.2? N, 75? 14? 28.3? W Water Depth 225 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 6 a SL 5Y 4/1 0 ma ns 0.7 - 1 None A2 18 c SL N 3 0 ma ns 0.7 - 1 10 None Cg1 40 c SL N 3.5 0 ma ns 0.7 - 1 2 Weak 2Cg2 87 c SiC 10Y 3/1 0 ma ms > 1 2 Strong 2Cg3 134 c SiC 10Y 3/1 0 ma ms > 1 3 Strong 2Cg4 153 a SiC 10Y 3/1 0 ma ms > 1 1 Strong 2Oab1 161 a Mk 10YR 2/2 2 5Y 5/6 Strong 2Oab2 168 - Mk 7.5YR 2.5/1 Strong Remarks: Profile description by D.M. Balduff; 22 July 2005 at 9:35 am. Sampled using a McCauley sampler. 415 Sample CB105 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 11? 15.0? N, 75? 15? 1.1? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a SiC 5Y 3/1 0 ma ss > 1 None A2 19 c L 5GY 3.5/1 5 2.5Y 5/6 0 ma ss 0.7 - 1 None Cg 63 c SiC 10Y 3/1 20 2.5Y 5/6 0 ma ms > 1 Strong Oab 78 c Mk 10YR 2/1 50 2.5Y 5/6 Strong Ab 85 c L 5Y 4/1 3 2.5Y 5/6 0 ma ss 0.7 - 1 Strong Cgb 105 - SiC 10Y 5/1 0 ma ms < 0.7 Strong Remarks: Profile description by D.M. Balduff; 22 July 2005 at 10:28 am. Sampled using a McCauley sampler. 416 Sample CB106 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 48.6? N, 75? 18? 7.1? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiL 5Y 3/1 0 ma ss > 1 None A2 16 c SL N 3 0 ma ss 0.7 - 1 2 None 2Cg1 53 c SiC 10Y 3/1 0 ma ms > 1 1 Strong 2Cg2 69 c SiC 10Y 3.5/1 10 10YR 4/4 0 ma ss > 1 Strong 2Cg3 165 c SiC 10Y 3.5/1 40 10YR 4/4 0 ma ss > 1 Strong 2Cg4 210 - SiC N 4 15 2.5Y 5/6 0 ma ms > 1 1 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 8:33 am. Sampled using a McCauley sampler. Worm tubes on surface. 417 Sample CB107 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 01? 56.7? N, 75? 18? 23.7? W Water Depth 240 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 6 a SiL 5Y 3/2 0 ma ns > 1 None Cg1 49 c SiCL 10Y 3/1 0 ma ms > 1 2 None Cg2 105 c SiC 10Y 3/1 25 2.5Y 5/6 0 ma ss > 1 Strong Cg3 165 g SiC 10Y 3.5/1 15 2.5Y 5/6 0 ma ms > 1 Strong Cg4 200 - SiC 10Y 3.5/1 7 2.5Y 5/6 0 ma ss > 1 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 9:28 am. Sampled using a McCauley sampler. 418 Sample CB108 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 3.0? N, 75? 18? 55.8? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a L 10Y 2.5/1 0 ma ss 0.7 - 1 None A2 17 c L 10Y 3/1 0 ma ms 0.7 - 1 3 None Cg1 57 c SiC 10Y 3/1 0 ma ss > 1 Weak Cg2 84 c SiC 10Y 3.5/1 0 ma ms > 1 Strong Cg3 97 - SiC 10Y 3.5/1 0 ma ss > 1 10 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 10:00 am. Sampled using a McCauley sampler. 419 Sample CB109 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 9.0? N, 75? 19? 29.7? W Water Depth 230 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL 5Y 4/1 0 ma ns > 1 None A2 15 c SiCL 10Y 3/1 0 ma ss > 1 5 Strong Cg1 71 c SiC 10Y 3/1 7 5Y 5/6 0 ma ss > 1 2 Strong Cg2 120 - SiC 10Y 3/1 5 5Y 5/6 0 ma ss > 1 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 10:22 am. Sampled using a McCauley sampler. 420 Sample CB110 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 9.4? N, 75? 19? 53.6? W Water Depth 240 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SiC 10Y 2.5/1 0 ma ms > 1 Strong Cg1 69 g SiC 10Y 3/1 0 ma ms > 1 Strong Cg2 100 a C 10Y 2.5/1 0 ma ms > 1 2 Strong Cg3 103 - SiC 10Y 3/1 0 ma ss > 1 15 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 10:47 am. Sampled using a McCauley sampler. 421 Sample CB111 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 13.4? N, 75? 20? 30.1? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiL 5Y 4/2 0 ma ss >> 1 A2 20 c SiC 10Y 2.5/1 0 ma ms > 1 Strong Cg1 42 g SiC 10Y 3/1 0 ma ms > 1 2 Strong Cg2 200 - SiC 10Y 3/1 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 26 July 2005 at 11:14 am. Sampled using a McCauley sampler. Surface was extremely shelly. 422 Sample CB112 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 04? 52.6? N, 75? 17? 36.7? W Water Depth 180 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiCL 5Y 4/2 0 ma ss > 1 A2 21 c CL 10Y 2.5/1 7 5Y 5/6 0 ma ms > 1 2 Cg1 54 c SiC 10Y 3.5/1 20 5Y 5/6 0 ma ss > 1 Strong Cg2 138 c SiC 10Y 3/1 0 ma ms > 1 1 Strong Cg3 184 - SiC 10Y 3.5/1 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 27 July 2005 at 8:43 am. Sampled using a McCauley sampler. Clam shell in horizon A2. 423 Sample CB113 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 7.7? N, 75? 17? 55.5? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiL 5Y 4/2 0 ma ss > 1 Strong A2 25 c SL 10Y 3/1 0 ma ss 0.7 - 1 Strong Cg1 46 c SiC 10Y 3/1 0 ma ms > 1 Strong Cg2 148 c SiC 5GY 4/1 20 2.5Y 5/6 0 ma ms > 1 Strong Cg3 199 - SiC 10Y 3/1 25 2.5Y 5/6 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 27 July 2005 at 9:16 am. Sampled using a McCauley sampler. 424 Sample CB114 Fine-loamy, Typic Sulfaquents (Fine-loamy, Fluvic Sulfiwassents) 38? 05? 21.5? N, 75? 18? 9.3? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 6 a SiL 5Y 4/2 0 ma ss > 1 A2 23 c SL 10Y 2.5/1 0 ma ss 0.7 - 1 Strong Cg1 63 c SiC 10Y 3/1 0 ma ms > 1 3 Strong Cg2 80 c SL 10Y 3/1 0 ma ss 0.7 - 1 Strong Cg3 210 - SiC 10Y 3/1 0 ma ms > 1 1 Strong Remarks: Profile description by D.M. Balduff; 27 July 2005 at 9:50 am. Sampled using a McCauley sampler. 425 Sample CB115 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 28.2? N, 75? 18? 38.9? W Water Depth 120 cm Boundary USDA Texture Redoximorphic Features Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Abun. % Color Gr. Shape Moist Const . n value Shells % Intensity of H 2 S A1 2 a SL 5Y 4/1 0 ma ss > 1 Strong A2 15 c SL 10Y 3/1 1 10YR 4/4 0 ma ms 0.7 - 1 1 Strong 2Cg1 50 c SiC 10Y 3/1 0 ma ms > 1 2 Strong 2Cg2 99 c SiC 5Y 4/1 15 10 10Y 5/1 2.5Y 4/1 10 2.5Y 5/6 0 ma ms > 1 Strong 2Cg3 159 c SiC 5Y 5/1 15 5Y 5/4 15 2.5Y 5/6 0 ma ms > 1 Strong 2Cg4 198 - SiC 2 2.5Y 5/6 0 ma ms > 1 2 Strong Remarks: Profile description by D.M. Balduff; 27 July 2005 at 10:15 am. Sampled using a McCauley sampler. 426 Sample CB116 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 05? 21.2? N, 75? 17? 25.6? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SL 5Y 4/1 0 ma ns > 1 A2 18 c SL 10Y 2.5/1 0 ma ss 0.7 - 1 Strong 2Cg1 62 c SiC 10Y 2.5/1 0 ma ss > 1 Faint 2Cg2 78 c SiC 10Y 3/1 3 2.5Y 3/3 0 ma ss > 1 Faint 2Cg3 103 - SiC 10Y 3/1 0 ma ss > 1 15 Strong Remarks: Profile description by D.M. Balduff; 27 July 2005 at 12:15 pm. Sampled using a McCauley sampler. 427 Sample CB117 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 01? 34.8? N, 75? 19? 48.1? W Water Depth 240 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 16 c L 10Y 2.5/1 0 ma ss 0.7 - 1 7 None Cg1 34 c SiC 10Y 3/1 0 ma ms > 1 3 Strong Cg2 97 c SiC 10Y 3/1 0 ma ss > 1 1 Strong Cg3 163 c CL 10Y 3/1 0 ma ms > 1 1 Strong Cg4 211 - L 10Y 3/1 0 ma ss 0.7 - 1 2 Strong Remarks: Profile description by D.M. Balduff; 11 August 2005 at 8:10 am. Sampled using a McCauley sampler. 428 Sample CB118 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 01? 9.3? N, 75? 21? 12.2? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 9 c SiC N 3 0 ma ms > 1 Faint Cg1 19 c SiC 10Y 3/1 0 ma ms > 1 Faint Cg2 117 c SiC CL 10Y 3/1 0 ma ss > 1 Strong Cg3 148 c SiC 10Y 3/1 10 2.5Y 3/3 0 ma ss > 1 1 Strong Cg4 191 c SiC 10Y 3/1 3 2.5Y 3/3 0 ma ss > 1 1 Strong Cg5 205 - SiC 10Y 3/1 0 ma ss > 1 Strong Remarks: Profile described by D. Balduff, 11 August 2005 at 9:21 am. Sampled using McCauley peat auger. Worm tubes on surface. 429 Sample CB119 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents) 38? 01? 1.8? N, 75? 22? 37.3? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 17 c C 10Y 3/1 0 ma ms > 1 None Cg1 44 c CL 10Y 3/1 0 ma ms > 1 1 Strong Cg2 73 c L 10Y 3/1 0 ma ss 0.7 - 1 1 None 2Cg3 99 - SL 10Y 3/1 N 3 (2) 0 ma ss 0.7 - 1 None Remarks: Profile description by D.M. Balduff; 11 August 2005 at 9:54 am. Sampled using a McCauley sampler. 430 Sample CB120 Coarse-loamy, Typic Sulfaquents (Coarse-loamy, Fluvic Sulfiwassents) 38? 01? 34.1? N, 75? 22? 8.7? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 12 c C 5Y 3/1 10YR 4/4 (2) 0 ma ss > 1 None Cg1 31 c CL 10Y 3/1 0 ma ss 0.7 - 1 None 2Cg2 56 c SL 10Y 3/1 7 10YR 3/3 0 ma ss 0.7 - 1 None 2Cg3 81 c SL 10Y 4/1 3 10YR 3/3 0 ma ss 0.7 - 1 Strong 2Cg4 102 - SL 10Y 4/1 5Y 4/6 (2) 0 ma ss 0.7 - 1 None Remarks: Profile description by D.M. Balduff; 11 August 2005 at 10:35 am. Sampled using a McCauley sampler. 431 Sample CB121 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 02? 0.5? N, 75? 22? 12.7? W Water Depth 140 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 12 c SiC N 3 0 ma ms > 1 2 Strong Cg1 52 c SiC 10Y 3/1 N 3 (15) 0 ma ms > 1 Strong Cg2 89 c SiC 10Y 3.5/1 0 ma ss > 1 Strong Cg3 197 c SiC 10Y 3/1 15 5Y 4/4 0 ma ss > 1 Strong Cg/Oa 204 a Mk SiC 10Y 3/1 25 5Y 4/4 0 ma ss > 1 Strong Oab 213 c Mk 10YR 2/2 45 5Y 4/4 Strong Cgb 216 - SiC 10Y 3/1 0 ma ns > 1 Strong Remarks: Profile description by D.M. Balduff; 11 August 2005 at 11:14 am. Sampled using a McCauley sampler. 432 Sample CB122 Fine-silty, Typic Sulfaquents (Fine-silty, Fluvic Sulfiwassents) 38? 00? 58.1? N, 75? 21? 35.5? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 4 a SiC 5Y 3.5/1 0 ma ss > 1 Strong Cg1 31 c SiC 10Y 2.5/1 N 2.5 (2) 2.5Y 3/3 (3) 0 ma ms > 1 Strong Cg2 132 c SiC 10Y 3/1 2 2.5Y 4/4 0 ma ss > 1 3 Strong Cg3 203 - SiC 10Y 3/1 20 2.5Y 4/4 0 ma ms > 1 Strong Remarks: Profile description by D.M. Balduff; 11 August 2005 at 12:09 pm. Sampled using a McCauley sampler. Worm tubes on surface. 433 Sample CB123 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 11? 34.4? N, 75? 12? 52.5? W Water Depth 130 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a fS 5Y 4/1 0 sg ns < 0.7 A2 24 c fS N 3 0 sg ns < 0.7 2 Strong Cg1 47 c LfS fS 10Y 3/1 0 sg ns < 0.7 5 Strong Cg2 109 c LfS LfS 10Y 3.5/1 2 2.5Y 3/1 0 sg ns < 0.7 Strong Cg3 148 c LfS N 3.5 0 sg ns < 0.7 10 Strong 2Cg4 160 - SC 10Y 2.5/1 0 ma ms > 1 3 Strong Remarks: Profile described by D. Balduff, 12 August 2005 at 10:48 am. Sampled using a vibracorer; depth inside core 69 cm, depth outside core 70 cm. 434 Sample CB124 Coarse-loamy, Haplic Sulfaquent (Coarse-loamy, Haplic Sulfiwassents) 38? 12? 42.6? N, 75? 11? 58.0? W Water Depth 100 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 6 c fS fS 10Y 3.5/1 0 sg sg < 0.7 2 None Cg1 48 c fS fS 10Y 3/1 0 sg sg < 0.7 2 None 2Cg2 70 a SiC SiCL 10Y 3/1 15 2.5Y 3/3 0 ma ms > 1 Strong 2Oab1 116 c Mk 10YR 2/2 2.5Y 6/6 Strong 2Oab2 130 c Mk 10YR 2/1 2.5Y 6/6 Strong 3Ab 136 c Mk L fSL 5Y 3/1 7 10YR 3/4 0 ma ms 0.7 - 1 Strong 3Cgb 157 - L fSL 10Y 3.5/1 5 2.5Y 5/4 0 ma ms 0.7 - 1 Strong Remarks: Profile described by D. Balduff, 12 August 2005 at 10:48 am. Sampled using a vibracorer; depth inside core 64 cm, depth outside core 65 cm. 435 Sample CB125 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 10? 22.0? N, 75? 13? 25.6? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a S 5Y 4/1 0 sg ns < 0.7 None A2 11 c S N 3 0 sg ns < 0.7 None Cg1 35 c SL 10Y 3/1 0 ma ss 0.7 - 1 3 None Cg2 65 c LS 10Y 3/1 1 2.5Y 5/6 0 sg ns < 0.7 Faint Cg3 98 c SL 10Y 3/1 3 2.5Y 5/6 0 ma ns 0.7 - 1 2 Faint Cg4 126 - LcS 5GY 4/1 sg ns < 0.7 10 Strong Remarks: Profile described by D. Balduff, 15 August 2005 at 9:25 am. Sampled using a vibracorer; depth inside core 152 cm, depth outside core 154 cm. 436 Sample CB126 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 10? 51.8? N, 75? 15? 4.0? W Water Depth 210 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a L 5Y 4/1 0 ma ns 0.7 - 1 None A2 36 c L 10Y 2.5/1 0 ma ss 0.7 - 1 2 Faint Cg1 120 c SiC 10Y 3/1 0 ma ss > 1 Strong Cg2 166 c SiC 10Y 3/1 7 2.5Y 2.5/1 0 ma ss > 1 Strong Oab 177 a Mk 10YR 2/1 Strong Ab 181 a Mk SiL 10YR 3/1 0 ma ss > 1 Strong Cgb 192 - SiC N 4 3 2.5Y 5/4 0 ma ms > 1 Faint Remarks: Profile described by D. Balduff, 15 August 2005 at 11:05 am. Sampled using a McCauley peat sampler. Worm tubes on surface. 437 Sample CB127 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 11? 42.5? N, 75? 15? 10.1? W Water Depth 180 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 22 c SiC 10Y 3/1 0 ma ms > 1 1 None Cg1 51 c SiC SiCL 5Y 4/1 0 ma ss >> 1 None Cg2 102 c SiC SiCL 10Y 3/1 0 ma ss > 1 Strong Cg3 169 c SiC 10Y 3/1 3 2.5Y 3/1 0 ma ss > 1 2 Strong Cg4 186 c Mk SiC 10Y 3/1 30 10YR 5/4 0 ma ms > 1 Strong Oab1 201 c Mk 10YR 2/1 Strong Oab2 224 c Mk 2.5Y 2.5/1 Strong Ab 230 a Mk L 10YR 2/1 10 2.5Y 6/6 0 ma ss > 1 Cgb 236 - L 10YR 3/1 7 10YR 2/1 0 ma ss > 1 Remarks: Profile described by D. Balduff, 12 August 2005 at 10:48 am. Sampled using a McCauley peat sampler. Worm tubes on surface. 438 Sample CB128 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 11? 36.1? N, 75? 14? 38.4? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SL 5Y 4/1 0 ma ss > 1 Strong A2 14 c SiCL N 3 0 ma ms > 1 Strong Cg1 26 c SiCL 10Y 3/1 3 10YR 3/4 0 ma ss > 1 5 Strong Cg2 69 c SiC 10Y 3/1 20 5Y 5/4 0 ma ss > 1 Strong Cg3 218 c SiC 10Y 3/1 15 2.5Y 5/6 0 ma ms > 1 Strong Cg4 247 a SiC 10Y 3/1 3 5Y 5/6 0 ma ms > 1 1 Strong Cg5 250 - Mk SiC 10YR 3/2 0 ma ms > 1 Strong Remarks: Profile described by D. Balduff, 19 August 2005 at 9:30 am. Sampled using a McCauley peat sampler. 439 Sample CB129 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 08? 48.2? N, 75? 14? 27.8? W Water Depth 300 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiC 5Y 4/1 0 ma ss > 1 None A2 33 c SiC 10Y 2.5/1 0 ma ss > 1 Strong Cg1 137 g SiC 10Y 3/1 0 ma ss > 1 Strong Cg2 194 c SiC 10Y 3.5/1 0 ma ss > 1 2 Strong 2Cg3 219 - SL 5GY 3.5/1 0 ma ns 0.7 - 1 10 Strong Remarks: Profile described by D. Balduff, 19 August 2005 at 10:47 am. Sampled using a McCauley peat sampler. 440 Sample CB130 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 04? 6.4? N, 75? 21? 22.0? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiC 5Y 4/1 0 ma ms > 1 None A2 21 c SiC SiCL 10Y 2.5/1 0 ma ms > 1 1 None Cg1 58 c SiC CL 10Y 3/1 3 2.5Y 5/4 0 ma ms > 1 3 None Cg2 125 SiCL Cg2 199 g SiC SiCL 10Y 3/1 0 ma vs > 1 1 Strong Cg3 275 CL Cg3 340 - SiC SiCL 10Y 3/1 0 ma ms > 1 2 Strong Remarks: Profile described by D. Balduff, 20 August 2005 at 10:12 am. Sampled using a McCauley peat sampler. Gastropod located at 201 cm. 441 Sample CB131 Sandy, Haplic Sulfaquent (Sandy, Haplic Sulfiwassents) 38? 10? 16.2? N, 75? 12? 33.9? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a LfS 5Y 4/1 0 sg ns < 0.7 None A2 9 c fS N 3 0 sg ns < 0.7 None Cg1 39 c fSL 10Y 3.5/1 0 ma ns 0.7 - 1 None Cg2 73 c fSl 10Y 3.5/1 3 10YR 2/1 0 ma ns 0.7 - 1 Strong Cg3 123 c L 5GY 3.5/1 5 10YR 2/1 0 ma ms > 1 Strong 2Cg4 161 - LfS 5GY 4/1 0 sg ns < 0.7 5 Strong Remarks: Profile described by D. Balduff, 22 August 2005 at 8:40 am. Sampled using a vibracorer; depth inside core 62 cm, depth outside core 60 cm. 442 Sample CB132 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 10? 51.2? N, 75? 12? 16.6? W Water Depth 110 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a LfS 5Y 4/1 0 sg ns < 0.7 15 Strong A2 10 c LfS N 3 0 sg ns < 0.7 15 Strong Cg1 22 c fS 10Y 2.5/1 0 sg ns < 0.7 1 Strong Cg2 77 c LfS 10Y 3.5/1 0 sg ns < 0.7 1 Strong Cg3 90 c LfS 5GY 4/1 3 10YR 3/1 0 sg ns < 0.7 3 Strong 2Cg4 155 - S N 4 0 sg ns < 0.7 Strong Remarks: Profile described by D. Balduff, 22 August 2005 at 10:00 am. Sampled using a vibracorer; depth inside core 76 cm, depth outside core 52 cm. 443 Sample CB133 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 11? 36.3? N, 75? 11? 39.9? W Water Depth 125 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 10 a L N 2.5 0 ma ns >> 1 Strong A2 23 c SL N 3 0 ma ns < 0.7 Strong Cg1 56 c LS 10Y 3/1 15 10YR 3/2 0 sg ns < 0.7 7 Strong Cg2 122 c S 10Y 4/1 2 10YR 3/2 0 sg ns < 0.7 3 Strong Cg3 183 c SL 10Y 3.5/1 2 10YR 3/2 0 ma ns < 0.7 2 Strong Cg4 196 - S 5GY 4/1 0 sg ns < 0.7 2 Strong Remarks: Profile described by D. Balduff, 22 August 2005 at 10:50 am. Sampled using a vibracorer; depth inside core 47 cm, depth outside core 36 cm. 444 Sample CB134 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 12? 10.6? N, 75? 14? 53.0? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiL 5Y 4/1 0 ma ns > 1 3 None A2 23 c SiL 10Y 2.5/1 0 ma ss > 1 2 None Cg1 92 c SiCL 10Y 4/1 0 ma ms > 1 None Cg2 109 c SiC 10Y 4/1 10 2.5Y 4/4 0 ma ss > 1 None Oab 118 c Mk 10YR 2/1 Strong 2Ab 134 c SL 5Y 4/1 15 5Y 5/4 0 ma ns 0.7 - 1 None 2Cgb1 162 c SL 10Y 5/1 2 5Y 5/4 0 ma ns < 0.7 None 2Cgb2 179 - LS 10Y 5/1 0 sg ns < 0.7 None Remarks: Profile described by D. Balduff, 23 August 2005 at 8:08 am. Sampled using a McCauley peat sampler. Worm tubes and bivalve shells on surface. 445 Sample CB135 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 12? 19.6? N, 75? 14? 59.1? W Water Depth 150 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a LfS 5Y 4/2 0 sg ns < 0.7 None A2 19 c S N 3 0 sg ns < 0.7 7 None Cg1 61 c LS 2.5Y 4/2 10 10YR 4/6 0 sg ns < 0.7 7 None Cg2 98 c LS 5Y 5/1 7 2.5Y 5/4 0 sg ns < 0.7 None Cg3 126 c S 5Y 5/1 2 2.5Y 5/4 0 sg ns < 0.7 None 2Cg4 174 - cS 10Y 6/1 0 sg ns < 0.7 Strong Remarks: Profile described by D. Balduff, 23 August 2005 at 8:08 am. Sampled using a vibracorer; depth inside core 86 cm, depth outside core 70 cm. Worm tubes on surface. 446 Sample CB136 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 12? 16.1? N, 75? 14? 56.2? W Water Depth 165 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fSl 5Y 4/1 0 ma ns < 0.7 None A2 18 c LS LfS 10Y 2.5/1 0 ma ns < 0.7 2 None Cg1 37 c SL L 10Y 3/1 0 ma ns 0.7 - 1 3 None 2Cg2 93 c SiC SiCL 10Y 3/1 0 ma ss > 1 2 Strong 2Cg3 146 c SiC SiCL 10Y 3/1 0 ma ms > 1 1 Strong 2Cg4 161 a SiC SiC 10Y 3/1 20 5Y 5/6 0 ma ss > 1 Strong 2Oab1 187 c Mk 10YR 3/2 Strong 2Oab2 205 c Mk 10YR 2/1 Strong 3Ab 211 - SL SL 2.5Y 3/1 0 ma ns 0.7 - 1 Strong Remarks: Profile described by D. Balduff, 23 August 2005 at 10:20 am. Sampled using a McCauley peat sampler. 447 Sample CB137 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 11? 37.1? N, 75? 14? 31.8? W Water Depth 225 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 3 a SiL 5Y 4/1 0 ma ns >> 1 None A2 10 c SiL N 3 0 ma ss > 1 None Cg1 64 c SiC 10Y 4/1 10 10YR 3/3 0 ma ms > 1 Strong Cg2 106 c SiC 10Y 3.5/1 15 2.5Y 6/8 0 ma ss > 1 Strong Cg3 174 c SiC 10Y 3.5/1 7 2.5Y 6/8 0 ma ss > 1 Strong Cg4 210 - SiC 10Y 3.5/1 3 2.5Y 5/4 0 ma ms > 1 Strong Remarks: Profile described by D. Balduff, 23 August 2005 at 10:59 am. Sampled using a McCauley peat sampler. 448 Sample CB138 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 11? 22.9? N, 75? 10? 39.3? W Water Depth 120 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 23 c fS N 3 0 sg ns < 0.7 1 None Cg1 47 c S N 4.5 0 sg ns < 0.7 2 None Cg2 130 c S N 5 0 sg ns < 0.7 Strong Cg3 149 - S N 4.5 0 sg ns < 0.7 Strong Remarks: Profile described by D. Balduff, 24 August 2005 at 8:40 am. Sampled using a vibracorer; depth inside core 79 cm, depth outside core 63 cm. 449 Sample CB139 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 11? 27.7? N, 75? 11? 18.9? W Water Depth 165 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fS 5Y 4/1 0 sg ns < 0.7 None A2 10 c fS N 3 3 10YR 2/1 0 sg ns < 0.7 None A3 21 c fS N 4 2 10YR 3/2 0 sg ns < 0.7 1 None Cg1 52 c fS N 4.5 1 10YR 5/6 0 sg ns < 0.7 2 Strong Cg2 67 c S N 5 0 sg ns < 0.7 Strong Cg3 87 c S N 5 0 sg ns < 0.7 7 Strong Cg4 144 - S N 5.5 0 sg ns < 0.7 1 Strong Remarks: Profile described by D. Balduff, 24 August 2005 at 9:22 am. Sampled using a vibracorer; depth inside core 70 cm, depth outside core 50 cm. Worm tubes on surface. Clam shell in Cg3 horizon. 450 Sample CB140 Sandy, Haplic Sulfaquent (Sulfic Psammowassents) 38? 10? 55.7? N, 75? 13? 23.0? W Water Depth 160 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fS 5Y 4/1 0 sg ns < 0.7 1 None A2 15 c fS N 2.5 0 sg ns < 0.7 2 Strong Cg1 36 c fS 10Y 3/1 0 sg ns < 0.7 Strong Cg2 96 c LfS 5GY 3.5/1 3 10YR 3/3 0 sg ns < 0.7 3 Strong Cg3 123 c LfS 10Y 3/1 0 sg ns < 0.7 3 Strong 2Cg4 147 c L 10Y 3/1 0 ma ss > 1 2 Strong 2Cg5 192 - fSL 10Y 3/1 0 ma ss 0.7 - 1 5 Strong Remarks: Profile described by D. Balduff, 24 August 2005 at 10:40 am. Sampled using a vibracorer; depth inside core 70 cm, depth outside core 42 cm. 451 Sample CB141 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 11? 38.8? N, 75? 13? 47.7? W Water Depth 220 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 4 a SiL 5Y 3/1 0 ma ns > 1 2 None A2 13 c SiL SL 10Y 2.5/1 0 ma ss > 1 10 None Cg1 23 c SiCL SL 10Y 3/1 0 ma ss > 1 25 None Cg2 46 c SiC CL 10Y 3/1 2.5Y 4/4 0 ma ms > 1 25 Strong Cg3 123 g SiC SiCL 10Y 3/1 0 ma ss > 1 Strong Cg4 174 - SiC SiC 10Y 3/1 0 ma ss > 1 2 Strong Remarks: Profile described by D. Balduff, 24 August 2005 at 12:00 pm. Sampled using a McCauley peat sampler. Worm tubes on surface. 452 Sample CB142 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 08? 52.7? N, 75? 16? 35.6? W Water Depth 200 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiL 5GY 4/1 0 ma ms > 1 1 Strong Cg1 36 g SiCL SiL 5GY 3/1 0 ma ms > 1 Strong Cg2 100 c SiCL SiCL 10Y 3/1 3 10YR 3/4 0 ma ms > 1 1 Strong Oab 131 c Mk 10YR 3/1 Strong Ab 134 c Mk L N 3 0 ma ms 0.7 - 1 Strong Bab 142 c L L 5Y 4/1 0 ma ms 0.7 - 1 Strong Cgb 149 - CL L 10Y 5/1 0 ma ss 0.7 - 1 Strong Remarks: Profile described by D. Balduff, 1 October 2005 at 1:54 pm. Sampled using a McCauley peat sampler. 453 Sample CB143 Fine-silty, Typic Sulfaquent (Fine-silty, Fluvic Sulfiwassents) 38? 09? 4.8? N, 75? 16? 39.2? W Water Depth 185 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Lab Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 3 a SiCL N 2.5 0 ma ss > 1 None Cg1 61 c SiCL L 10Y 3/1 0 ma ss > 1 Strong Cg2 95 c L L 10Y 3/1 2 2.5Y 3/1 0 ma ms > 1 Strong Cg3 108 a L L 10Y 3.5/1 0 ma ms 0.7 - 1 Strong 2Cg4 137 - C SiL 5GY 5/1 0 ma vs < 0.7 None Remarks: Profile described by D. Balduff, 1 October 2005 at 2:37 pm. Sampled using a McCauley peat sampler. 454 Sample CB144 Fine-loamy, Typic Sulfaquent (Fine-loamy, Fluvic Sulfiwassents) 38? 09? 8.0? N, 75? 16? 38.1? W Water Depth 175 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A1 2 a fS 5Y 4/1 0 sg ns < 0.7 1 None A2 15 c fS N 2.5 0 sg ns < 0.7 2 Strong Cg1 36 c fS 10Y 3/1 0 sg ns < 0.7 Strong Cg2 96 c LfS 5GY 3.5/1 3 10YR 3/3 0 sg ns < 0.7 3 Strong Cg3 123 c LfS 10Y 3/1 0 sg ns < 0.7 3 Strong 2Cg4 147 c L 10Y 3/1 0 ma ss > 1 2 Strong 2Cg5 192 - fSL 10Y 3/1 0 ma ss 0.7 - 1 5 Strong Remarks: Profile described by D. Balduff, 1 October 2005 at 3:07 pm. Sampled using a McCauley peat sampler. 455 Sample CB145 Fine-silty, Terric Sulfisaprists (Sapric Sulfiwassists) 38? 09? 16.2? N, 75? 16? 40.0? W Water Depth 20 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 6 c Mk SiC 5Y 4/1 0 ma ss > 1 Strong Oa 34 c Mk 10YR 3/3 Strong Cg 51 a Mk SiC 2.5Y 4/2 0 ma ms > 1 Strong O'a 69 a Mk 10YR 2/1 Strong Cg1 106 c Mk SiC 5GY 3.5/1 4 10YR 4/4 0 ma ss > 1 Strong Cg2 143 a SiC 5GY 3/1 20 10YR 4/6 0 ma ss > 1 Strong Oab 162 - Mk 10YR 2/1 Strong Remarks: Profile described by D. Balduff, 17 August 2005 at 12:03 pm. Sampled using a vibracorer. 456 Sample CB146 Fine-silty, Terric Sulfisaprists (Sapric Sulfiwassists) 38? 12? 25.10? N, 75? 15? 2.50? W Water Depth 40 cm Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S A 2 a SL 5Y 4/1 0 ma ss <0.7 Strong Cg 6 c SiC 10Y 3.5/1 10 2.5Y 5/6 0 ma ss >1 Strong Oa 24 c Mk 5Y 3/2 Strong C?g 39 c MkSiCL 10Y 3.5/1 0 ma ss >1 Strong Oab1 71 c Mk 5Y 3/2 Strong Oab2 103 c Mk 10YR 2/1 Strong C?g 160 c SiC 5GY 3.5/1 25 5Y 6/6 0 ma ss >1 Strong Oab 210 c Mk 10YR 2/2 Strong 2Ab 220 c L 10YR 2/1 7 2.5Y 4/4 0 ma ss 0.7-1 Strong 2Cgb 229 - SL 10Y 3/1 3 2.5Y 4/4 0 ma ss <0.7 Strong Remarks: Profile described by D. Balduff, 18 August 2005 at 10:57 am. Sampled using McCauley peat sampler. Worm tubes on surface. 457 Sample M01 38? 09? 16.6? N, 75? 16? 40.2? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oa 5 a Mk 2.5Y 3/2 None Oe 31 c Mp 10YR 3/3 Strong Oa1 53 c Mk 2.5Y 2.5/1 Strong Oa2 72 c Mk 10YR 2/1 Strong Oa3 104 c Mk 2.5YR 3/4 None Cg 127 c Mk SiL 5Y 3/1 20 10YR 3/2 0 ma ss > 1 Strong Oab 146 c Mk 5Y 4/2 Strong Ab 151 a Mk SiL 5Y 3/2 20 10YR 3/2 0 ma ss > 1 Strong Cgb 193 c Mk SiCL 10Y 3/1 10 2.5Y 5/4 0 ma ms > 1 Strong A'b 203 c Mk SiCL 10Y 3/1 20 2.5Y 5/4 0 ma ss > 1 Strong Cgb1 225 a SiCL 10Y 3/1 5 2.5Y 6/6 0 ma ss > 1 None 2Cgb2 243 - SCL 10Y 4/1 3 2.5Y 5/4 0 ma ms < 0.7 None Remarks: Profile described by D. Balduff, 17 August 2005 at 8:30 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 458 Sample M02 38? 09? 17.9? N, 75? 16? 40.3? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe 30 c Mp 2.5Y 3/1 0 Strong Oa1 46 c Mk 10YR 3/2 0 Strong Oa2 70 c Mk 5Y 4/1 0 Strong Oa3 84 c Mk 10Y 2/1 0 Strong Oa4 91 c Mk N 2.5 0 Strong Cg1 117 c SiCL 10YR 2.5/1 25 2.5Y 6/4 0 ma ss > 1 Strong Cg2 158 c Mk SiCL 5Y 4/2 20 2.5Y 6/4 0 ma ss > 1 Strong 2Cg3 164 a SL 5Y 5/2 5 2.5Y 6/4 0 ma ss 0.7 - 1 Strong 2Cg4 234 c SCL N 5 5 2.5Y 6/4 0 ma ss < 0.7 None 2Cg5 238 - LS N 5 0 sg ns < 0.7 None Remarks: Profile described by D. Balduff, 17 August 2005 at 9:45 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 459 Sample M03 38? 09? 19.5? N, 75? 16? 41.2? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr. Shape Wet Const. n value Shells % Intensity of H 2 S Oe 50 c Mp 10YR 3/2 Strong Oa1 90 c Mk 10YR 4/3 Strong Oa2 108 c Mk 10Y 3/1 tree 10YR 4/6 Strong Oa3 130 c Mk 10Y 3.5/1 Strong Oa4 149 a Mk N 2.5 Strong 2Cg 170 - SL/SCL 10Y 6/1 10GY 5/1 (5) 0 ma ms < 0.7 Strong Remarks: Profile described by D. Balduff, 17 August 2005 at 10:40 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 460 Sample M04 38? 09? 21.5? N, 75? 16? 42.1? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe 42 c Mp 2.5Y 3/3 Strong Oa1 55 c Mk 5Y 3/1 Strong Oa2 80 c Mk 2.5Y 2.5/1 Strong A 98 a Mk L 5Y 3/1 20 2.5Y 5/4 0 ma ss 0.7 - 1 Strong Cg 143 - SCL 10Y 5/1 7 5Y 7/6 0 ma ss < 0.7 Strong Remarks: Profile described by D. Balduff, 17 August 2005 at 11:00 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 461 Sample M07 38? 12? 27.4? N, 75? 15? 4.4? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe1 15 c Mp 2.5Y 3/1 Strong Oe2 51 c Mp 2.5Y 3/1 Strong Oa 83 c Mk 2.5Y 4/2 Strong Oe 116 a Mp 10YR 2/1 Strong A 127 a Mk SiL 10YR 2/1 0 ma ss > 1 Strong Cg1 155 c SiL 5Y 4/2 15 10YR 3/4 0 ma ss > 1 Strong Cg2 177 c Mk SiL 10YR 3/2 0 ma ss > 1 Strong Oab 193 c Mk 10YR 2/1 Strong 2Ab 200 c L 5Y 2.5/2 0 ma ss 0.7 - 1 Strong 2Cgb1 240 c SL 10Y 4/1 5 2.5Y 5/4 0 ma ss 0.7 - 1 Strong 2Cgb2 268 - SL 10Y 5/1 2 10YR 3/4 0 ma ns 0.7 - 1 Strong Remarks: Profile described by D. Balduff, 18 August 2005 at 8:24 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 462 Sample M08 38? 12? 29.6? N, 75? 15? 6.0? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe 25 c Mp 2.5Y 3/2 Strong A 39 c Mk SiCL 10Y 4/1 0 ma ss > 1 Strong Cg 52 c Mk SiC 5Y 3/2 0 ma ss > 1 Strong O'e 82 c Mp 10YR 2/1 Strong C'g 177 c SiC 5GY 4/1 20 2.5Y 5/6 0 ma ss > 1 Strong Oa 192 c Mk 2.5Y 3/3 Strong Ab 203 c Mk SiCL 5Y 4/2 0 ma ss > 1 Strong Oab 242 c Mk 10YR 2/1 Strong Cgb 258 c SiL 5Y 3/2 0 ma ss 0.7 - 1 Strong A'b 271 c Mk L 10YR 2/1 0 ma ss 0.7 - 1 Strong 2C'gb 295 - SL 10YR 2/2 0 ma ns 0.7 - 1 Strong Remarks: Profile described by D. Balduff, 18 August 2005 at 9:06 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 463 Sample M09 38? 12? 31.9? N, 75? 15? 8.8? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe 4 a Mp 2.5Y 4/2 Strong Oa 15 c Mk 2.5Y 4/2 Strong Cg 75 c Mk SiCL 5Y 3/1 0 ma ss > 1 Strong O'a 102 c Mk 10YR 2/1 Strong C'g 187 c Mk SiC 5Y 4/2 0 ma ss > 1 Strong Oab 224 c Mk 10YR 2/1 Strong 2Ab 237 c Mk L 10YR 2/2 0 ma ss 0.7 - 1 Strong 2Cgb1 244 a SL 2.5Y 2.5/1 0 ma ns 0.7 - 1 Strong 2Cgb2 284 - SL 5Y 5/1 0 ma ns < 0.7 Strong Remarks: Profile described by D. Balduff, 18 August 2005 at 9:46 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 464 Sample M10 38? 12? 25.8? N, 75? 15? 3.0? W Boundary USDA Texture Organic Fragments Structure Horiz. Depth Dist. Field Matrix Color Abun. % Color Gr . Shape Wet Const. n value Roots % Shells % Intensity of H 2 S Oe 6 a Mk 5Y 3/2 Strong Cg 31 c C 10Y 3/1 15 10YR 3/4 0 ma ss 0.7 - 1 Strong Oa1 66 c Mk 2.5Y 5/3 Strong Oa2 97 a Mk 10YR 4/3 Strong Oa3 125 a Mk 10YR 2/1 Strong C'g 166 a SiC 5GY 4/1 15 2.5Y 5/6 0 ma ss > 1 Strong Oab1 183 c Mk 2.5Y 2.5/1 Strong Oab2 203 c Mk 10YR 3/2 Strong Oab3 220 c Mk 10YR 2/2 Strong 2Cgb1 261 c SL 5GY 4/1 0 ma ss < 0.7 Strong 2Cgb2 300 - SCL 5Y 5/2 5Y 5/4 (3) 0 ma ss < 0.7 Strong Remarks: Profile described by D. Balduff, 18 August 2005 at 10:32 am. Sampled using McCauley peat sampler and bucket auger. Marsh grass on surface. 465 Observation O01 21 September 2004 38? 08? 4.67? N, 75? 14? 5.15? W Water Depth 220 cm 0-8 cm ? n value >1 8-20 cm ? n value <0.7 Observation O02 21 September 2004 38? 08? 9.49? N, 75? 14? 13.38? W Water Depth 280 cm 0-40 cm ? n value >1 40-50 cm ? sand, n value <0.7 Observation O03 22 September 2004 38? 09? 11.9? N, 75? 16? 47.59? W 0-90 cm ?sample did not contain an organic horizon, clam shell at 15 cm, organic fragments located at bottom of sample 90 cm ? sandy loam Observation O04 7 June 2005 38? 07? 3.06? N, 75? 17? 28.92? W Water Depth 150 cm A1 ? 0-4 cm ? oxidized surface Cg ? 4-16 cm Oab ? 16-60 cm Ab ? 60-69 cm Observation O05 7 June 2005 38? 07? 6.9? N, 75? 17? 39.6? W Water Depth 30 cm A ? 0-25 cm ? coarse sand with 15% coarse fragments, light brownish gray (2.5Y 6/2) Cg1 ? 25-40 cm ? medium sand, gray (2.5Y 6/1) Cg2 ? 40-51 cm ? medium sand, gray (2.5Y 5/1) Cg3 ? 51-62 cm ? loamy sand with 5% coarse fragments, very dark gray (2.5Y 3/1) Observation O06 8 June 2005 38? 09? 35.04? N, 75? 13? 53.88? W A ? 0-30 cm ? loam, black (N 2.5/) Cg ? 30-50 ? sandy loam with some shells 466 Observation O07 30 June 2005 38? 04? 47.0? N, 75? 19? 44.2? W A1 ? 0-13 cm ? loamy sand, olive gray (5Y 4/2) A2 ? 13-26 cm ? loamy sand, greenish black (10Y 2.5/1) Cg1 ? 26-36 cm ? loamy sand, greenish black (10Y 2.5/1) with 30% dark gray (5Y4/1) and pale olive (5Y 6/4) redoximorphic features Cg2 ? 36-56 cm ? sandy loam, 60% pale olive (5Y 6/3) and 40% very dark greenish gray (10Y 3/1) Observation O08 11 August 2005 38? 01? 39.3? N, 75? 20? 51.1? W 0-50 cm ? sandy loam, very dark greenish gray (10Y 3/1), 10% large shells 50 cm ? sand Observation O09 11 August 2005 38? 01? 41.9? N, 75? 20? 10.5? W 0-50 cm ? sandy loam, very dark greenish gray (10Y 3/1), 10% large shells 50 cm ? sand Observation O10 11 August 2005 38? 01? 21.8? N, 75? 22? 9.6? W 0-50 cm ? silty clay, very dark greenish gray (10Y 3/1) 50 cm ? very shelly horizon Observation O11 22 August 2005 38? 07? 1.7? N, 75? 17? 1.0? W A1 ? 0-2 cm Cg1 ? 2-47 cm ? silty clay, very dark greenish gray (10Y 3/1) 2Cg2 ? 47-57 cm ? sandy loam, very dark greenish gray (10Y 3/1), 3% shells Observation O12 11 August 2005 38? 01? 38.2? N, 75? 20? 34.0? W Water Depth 210 cm Surface horizon ? sand, very shelly surface Observation O13 12 August 2005 38? 10? 21.9? N, 75? 14? 9.8? W Water Depth 210 cm Surface horizon ? sand 467 Observation O14 19 August 2005 38? 07? 37.0? N, 75? 14? 39.0? W Water Depth 280 cm 0-20 cm ? silty clay 20 cm ? sand, n value <0.7 Observation O15 19 August 2005 38? 08? 49.7? N, 75? 14? 51.2? W Water Depth 270 cm Worm tubes on surface A1 ? 0-2 cm ? fine sandy loam, black (N 2.5/) A2 ? 2-12 cm ? fine sandy loam, greenish black (10Y 2.5/1), 1% shells Cg ? 12-30 cm ? sandy loam, very dark greenish gray (10Y 3/1), 3% shells Observation O16 23 August 2005 38? 11? 39.9? N, 75? 10? 33.7? W Water Depth 120 cm A ? 0-2 cm ? fine sandy loam, black (N 2.5/), no odor Cg1 ? 2-40 cm ? loamy fine sand, very dark gray (N 3/), 3% shells, no odor Cg2 ? 40-60 cm ? sand, gray (N 5/), 1% shells, faint odor Observation O17 23 August 2005 38? 12? 23.7? N, 75? 15? 1.0? W Water Depth 140 cm A ? 0-2 cm ? sandy loam, dark gray (5Y 4/1), no odor Cg ? 2-30 cm ? loamy sand, very dark greenish gray (10Y 3/1), no odor 468 Appendix D: Total Carbon, Organic Carbon, and Calcium Carbonate Data 469 Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB01 A, 0-14 cm VS 0.85 0.16 0.76 0.76 0.14 0.74 0.09 0.8 0.4-1.1 CB01 Cg1, 14-76 cm NE 0.44 0.34 0.44 0.34 CB01 Cg2, 76-103 cm NE 0.82 0.29 0.82 0.29 CB01 Cg3, 103-170 cm NE 1.56 1.36 1.56 1.36 CB01 Cg4, 170-210 cm NE 3.09 1.11 3.09 1.11 CB04 A, 0-6 cm SL 11.04 0.65 11.51 10.52 0.62 11.47 0.52 4.4 0.0-9.5 CB04 Cg1, 6-32 cm NE 11.66 2.62 11.66 2.62 CB04 Cg2, 32-111 cm NE 11.34 9.57 11.34 9.57 CB04 Cg3, 111-149 cm NE 9.64 3.99 9.64 3.99 CB06 A, 0-3 cm NE 13.99 0.18 5.19 13.99 0.18 5.19 CB06 Cg1, 3-59 cm NE 14.11 3.97 14.11 3.97 CB06 2Cg2, 59-81 cm NE 2.59 0.54 2.59 0.54 CB06 2Cg3, 81-107 cm NE 2.55 0.68 2.55 0.68 CB09 A1, 0-2 cm NE - - 3.82 - - 3.82 CB09 A2, 2-16 cm NE 5.22 1.02 5.22 1.02 CB09 Cg1, 16-22 cm NE 4.64 0.41 4.64 0.41 CB09 Cg2, 22-42 cm NE 2.46 0.92 2.46 0.92 CB09 Cg/Bgb, 42-53 cm NE 1.40 0.29 1.40 0.29 CB09 2Bgb, 53-76 cm NE 1.81 0.74 1.81 0.74 CB09 2Bwb1, 76-98 cm NE 1.16 0.43 1.16 0.43 CB09 2Bwb2, 98-108 cm NE 0.30 0.06 0.30 0.06 CB09 2BCgb, 108-118 cm NE 0.33 0.06 0.33 0.06 CB09 2Cgb1, 118-133 cm NE 0.32 0.09 0.32 0.09 CB09 2Cgb2, 133-151 cm NE 0.16 0.04 0.16 0.04 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 470 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB10 A, 0-17 cm NE 1.89 0.40 4.42 1.89 0.40 3.99 CB10 Cg1, 17-51 cm NE 2.24 0.96 2.24 0.96 CB10 Cg2, 51- 64 cm ST 7.90 1.19 5.07 0.77 2.83 23.6 21.1-26.1 CB10 2Cg3, 64-84 cm NE 5.98 1.61 5.98 1.61 CB10 3Cg4, 84-89 cm NE 3.21 0.22 3.21 0.22 CB10 3Cg5, 89-134 cm NE 0.17 0.10 0.17 0.10 CB11 A1, 0-2 cm - - - 30.19 - - 30.09 CB11 A2, 2-12 cm VS 7.87 0.97 7.02 0.86 0.85 7.0 3.6-10.4 CB11 Cg1, 12-36 cm NE 19.56 4.62 19.56 4.62 CB11 Cg2, 36-56 cm NE 42.17 4.87 42.17 4.87 CB11 Oab1, 56-83 cm NE 157.00 12.28 157.00 12.28 CB11 Oab2, 83-109 cm NE 212.20 11.39 212.20 11.39 CB11 2Ab, 109-115 cm NE 71.30 3.10 71.30 3.10 CB11 2Cgb, 115-122 cm NE 22.32 2.30 22.32 2.30 CB16 A1, 0-2 cm VS 1.11 0.03 2.20 0.87 0.02 2.13 0.24 2.0 1.6-2.4 CB16 A2, 2-22 cm SL 1.05 0.19 0.69 0.03 0.09 0.8 0.5-1.1 CB16 Cg1, 22-37 cm NE 2.17 0.42 2.17 0.17 CB16 Cg2, 37-67 cm NE 2.78 1.23 2.78 1.23 CB16 Cg3, 67- 80 cm NE 1.04 0.19 1.04 0.19 CB16 Cg4, 80-114 cm SL 0.49 0.22 0.35 0.15 0.14 1.2 1.0-1.4 CB16 Cg5, 114-187 cm NE 1.39 1.52 1.39 1.52 CB16 Cg6, 187-215 cm VS 0.41 0.15 0.39 0.14 0.02 0.1 0.0-0.3 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 471 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB17 A, 0-8 cm NE 2.69 0.32 3.68 2.69 0.32 3.49 CB17 Cg/A, 8-32 cm VS 1.46 0.54 1.35 0.50 0.11 0.9 0.3-1.6 CB17 Cg1, 32-54 cm NE 6.21 1.50 6.21 1.50 CB17 Cg2, 54-77 cm VS 4.43 1.19 3.91 1.04 0.52 4.4 2.5-6.3 CB17 2Cg3, 77-102 cm NE 0.42 0.14 0.42 0.14 CB17 2Cg4, 102-148 cm NE 0.23 0.14 0.23 0.14 CB18 A, 0-8 cm - - - - - 11.63 CB18 Cg, 8-50 cm NE 15.23 5.54 11.63 15.23 5.54 CB18 Cg, 50-100 cm NE 12.37 6.09 12.37 6.09 CB18 Cg, 100-150 cm NE 13.89 4.83 13.89 4.83 CB18 Cg, 150-200 cm VS 12.56 6.28 11.30 5.65 1.26 10.4 4.9-15.9 CB18 Cg, 200-250 cm SL 13.09 6.68 13.09 6.68 0.00 0.0 2.0-13.8 CB20 A, 0-8 cm NE 12.79 0.65 8.50 12.79 0.65 8.13 CB20 Cg1, 8-32 cm NE 9.59 4.33 9.59 4.33 CB20 Cg2, 32-60 cm VS 5.39 2.06 4.75 1.81 0.64 5.4 3.0-7.7 CB20 Cg3, 60-115 cm VS 4.10 2.01 3.76 1.84 0.34 2.8 1.0-4.6 CB21 A1, 0-2 cm SL - - 22.60 - - 22.49 CB21 A2, 2-18 cm SL 22.19 2.66 21.26 2.54 0.93 7.7 0.0-18.1 CB21 Oab, 18-58 cm NE 201.60 16.65 201.60 16.65 CB21 Ab, 58-62 cm NE 25.87 0.81 25.87 0.81 CB21 BAgb, 62-71 cm NE 10.43 1.32 10.43 1.32 CB21 Btgb, 71-96 cm NE 3.23 1.17 3.23 1.17 CB21 Cgb, 96-134 cm NE 0.17 0.09 0.17 0.09 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 472 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB24 Oa/Cg NE 104.80 104.80 CB24 Cg/Oa NE 92.51 92.51 CB26 A, 0-2 cm NE 0.93 0.03 34.16 0.93 0.03 34.16 CB26 Cg, 2-28 cm NE 1.91 0.80 1.91 0.80 CB26 A?, 28-50 cm NE 71.83 6.05 71.83 6.05 CB26 C?g, 50-70 cm NE 45.70 5.28 45.70 5.28 CB26 Cg/Oab, 70-103 cm NE 186.20 24.21 186.20 24.21 CB26 Oab, 103-132 cm NE 188.40 26.21 188.40 26.21 CB26 Ab, 132-137 cm NE 43.63 1.18 43.63 1.18 CB26 Btgb, 137-150 cm NE 15.71 3.15 15.71 3.15 CB31 A2, 4-22 cm ST 22.86 3.06 9.06 13.11 1.75 5.25 9.75 81.3 74.9-87.6 CB31 Cg1, 22-62 cm VE 22.30 4.36 10.55 2.06 11.75 97.9 92.8-103.1 CB31 Cg2, 62-112 cm SL 13.32 2.15 11.66 1.88 1.66 13.9 8.2-19.5 CB39 A1, 0-1 cm - - 6.82 6.79 CB39 A2, 1-12 cm VS 18.47 0.97 17.91 0.94 0.56 4.7 0.0-13.4 CB39 Cg1, 12-43 cm NE 13.17 3.45 13.17 3.45 CB39 Cg2, 43-57 cm NE 14.08 1.05 14.08 1.05 CB39 Cg3, 57-126 cm NE 9.71 2.17 9.71 2.17 CB39 2Cg4, 126-161 cm NE 3.89 1.14 3.89 1.14 CB39 2Cg5, 161-198 cm NE 1.89 1.01 1.89 1.01 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 473 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB41 A2, 3-17 cm SL 6.76 1.24 9.94 5.66 1.04 6.89 1.10 9.1 6.4-11.9 CB41 Cg1, 17-52 cm ST 16.62 6.66 10.13 4.06 6.49 54.0 49.1-59.0 CB41 Cg2, 52-143 cm SL 11.26 3.87 9.87 3.39 1.39 11.6 6.8-16.4 CB45 A, 0-6 cm VS 2.26 0.18 1.86 2.06 0.17 1.73 0.20 1.6 0.6-2.6 CB45 Cg/A, 6-33 cm VS 0.70 0.26 0.62 0.24 0.08 0.6 0.3-0.9 CB45 Cg1, 33-88 cm VS 1.22 0.83 1.16 0.79 0.06 0.5 0.0-1.1 CB45 Cg2, 88-99 cm VS 3.18 0.43 2.93 0.40 0.25 2.1 0.7-3.5 CB45 2Cg3, 99-142 cm VS 18.38 6.67 17.48 6.35 0.90 7.4 0.0-15.9 CB45 2Cg4, 142-186 cm VS 32.27 8.93 31.65 8.76 0.62 5.2 0.0-20.6 CB46 A, 0-5 cm - - - 24.85 - - 21.70 CB46 Cg1, 5-19 cm NE 12.17 6.79 12.17 6.79 CB46 Cg2, 19-40 cm VS 11.55 5.39 10.98 5.12 0.57 4.8 0.0-10.1 CB46 Cg3, 40-82 cm NE 11.61 8.10 11.61 8.10 CB46 Cg4, 82-126 cm ST 22.22 11.16 8.18 4.11 14.04 117.0 113.0-120.9 CB50 A1, 0-3 cm - - - 11.36 - - 6.28 CB50 A2, 3-21 cm VE 15.59 2.83 5.95 1.08 9.64 8.03 77.4-83.2 CB50 Cg/A, 21-45 cm ST 14.03 3.60 6.17 1.58 7.86 65.5 62.5-68.5 CB50 Cg1, 45-60 cm ST 10.82 1.94 6.55 1.17 4.27 35.6 32.4-38.8 CB50 Cg2, 60-92 cm SL 6.25 2.52 5.10 2.06 1.15 9.6 7.1-12.1 CB50 Cg3, 92-160 cm SL 4.44 3.98 3.64 3.26 0.08 6.7 4.9-8.5 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 474 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB52 A1 & A2 0-10 cm VS 7.22 0.40 9.26 6.46 0.35 8.56 0.76 6.3 3.2-9.5 CB52 Cg1, 10-21 cm VS 9.56 0.86 9.04 0.81 0.52 4.4 0.0-8.8 CB52 2Cg2, 21-39 cm SL 12.51 1.62 11.57 1.49 0.94 7.8 2.2-13.5 CB52 2Cg3, 39-59 cm SL 15.67 2.28 14.14 2.06 1.53 12.7 5.9-19.6 CB52 2Cg4, 59-86 cm VS 18.17 2.94 16.95 2.74 1.22 10.2 2.0-18.4 CB52 2Cg5, 86-115 cm SL 10.43 2.43 9.77 2.27 0.66 5.5 0.7-10.2 CB52 2Cg6, 115-138 cm VS 6.75 1.30 6.13 1.18 0.62 5.2 2.2-8.2 CB55 A1, 0-3 cm - - - 4.03 - - 3.44 CB55 A2, 3-12 cm SL 3.38 0.37 2.24 0.25 1.14 9.5 8.4-10.6 CB55 Cg1, 12-41 cm VS 3.99 1.39 3.71 1.29 0.28 2.4 0.6-4.2 CB55 Cg2, 41-90 cm VS 2.87 1.68 2.40 1.40 0.47 3.9 2.7-5.1 CB55 2Cg3, 90-143 cm SL 5.24 3.16 4.40 2.65 0.84 7.1 4.9-9.2 CB55 2Cg4, 143-162 cm NE 9.65 2.46 9.65 2.46 CB55 2Cg5, 162-198 cm NE 9.86 4.41 9.86 4.41 CB56 A1, 0-2 cm - - - 2.98 - - 2.66 CB56 A2, 2-10 cm VS 2.79 0.27 2.72 0.27 0.07 0.6 0.0-1.9 CB56 Cg1, 10-31 cm VS 1.38 0.40 1.26 0.36 0.12 0.9 0.3-1.6 CB56 Cg2, 31-49 cm VS 1.93 0.53 0.92 0.25 1.01 8.4 8.0-8.9 CB56 Cg3, 49-72 cm NE 3.49 1.07 3.49 1.07 CB56 Cg4, 72-90 cm NE 2.50 0.60 2.50 0.60 CB56 Cg5, 90-122 cm NE 0.87 0.36 0.87 0.36 CB56 Cg6, 122-137 cm NE 2.69 0.57 2.69 0.57 CB56 2Ab, 137-154 cm ST 16.34 2.54 11.17 1.73 5.18 43.1 37.7-48.6 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 475 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB58 A1, 0-3 cm - - - 4.56 - - 3.48 CB58 A2, 3-14 cm VS 4.22 0.68 2.18 0.35 2.04 17.0 16.0-18.1 CB58 Cg1, 14-37 cm SL 4.98 1.76 3.96 1.40 1.02 8.5 6.6-10.4 CB58 Cg2, 37-106 cm VS 4.14 2.32 3.38 1.89 0.76 6.4 4.7-8.0 CB58 2Cg3, 106-162 cm NE 10.31 6.84 10.31 6.84 CB59 A1, 0-5 cm VS 25.28 0.34 16.76 24.39 0.33 16.75 0.89 7.5 0.0-19.3 CB59 A2, 5-24 cm NE 28.29 2.74 28.29 2.74 CB59 Cg1, 24-35 cm NE 62.23 2.28 62.23 2.28 CB59 Cg2, 35-74 cm NE 57.11 9.03 57.11 9.03 CB59 Cg3, 74-86 cm NE 24.37 1.43 24.37 1.43 CB59 Cg4, 86-127 cm NE 11.74 2.76 11.74 2.76 CB67 A1, 0-2 cm - - - 15.91 - - 15.64 CB67 A2, 2-13 cm SL 9.19 0.90 8.00 0.78 1.19 9.9 6.0-13.8 CB67 Cg/A, 13-35 cm SL 12.13 4.24 11.88 4.16 0.25 2.1 0.0-7.8 CB67 2Cg1, 35-73 cm NE 23.09 7.90 23.09 7.90 CB67 2Cg2, 73-135 cm VS 13.96 6.61 13.63 6.45 0.33 2.7 0.0-9.4 CB70 A1, 0-5 cm - - - 10.03 - - 10.08 CB70 A2, 5-19 cm SL 10.24 1.02 9.72 0.97 0.52 4.3 0.0-9.0 CB70 2Cg1, 19-44 cm SL 11.92 2.16 11.30 2.05 0.62 5.1 0.0-10.6 CB70 2Cg2, 44-78 cm VS 15.36 4.24 15.12 4.18 0.24 2.0 0.0-9.4 CB70 2Cg3, 78-92 cm NE 18.46 1.86 18.46 1.86 CB70 2Cg4, 92-127 cm NE 13.70 3.24 13.70 3.24 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 476 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB72 A1, 0-2 cm - - - 12.63 - - 12.04 CB72 A2, 2-13 cm VS 11.14 1.65 10.61 1.58 0.53 4.4 0.0-9.6 CB72 Cg1, 13-48 cm VS 11.93 7.73 11.42 7.40 0.51 4.3 0.0-9.8 CB72 Cg2, 48-69 cm VS 9.06 1.30 8.91 1.28 0.15 1.2 0.0-5.6 CB72 Cg3, 69-107 VS 7.46 2.39 6.86 2.20 0.60 4.9 1.6-8.3 CB74 A1, 0-2 cm - - - 3.72 - - 3.56 CB74 A2, 2-19 cm VS 8.01 1.25 7.51 1.17 0.50 4.2 0.5-7.8 CB74 Cg1, 19-55 cm SL 2.46 1.02 2.36 0.98 0.10 0.8 0.0-2.0 CB74 Cg2, 55-89 cm VS 2.41 1.04 2.36 1.02 0.05 0.5 0.0-1.6 CB74 Cg3, 89-109 cm VS 3.45 0.75 3.32 0.72 0.13 1.1 0.0-2.7 CB74 2Cg4, 109-142 cm VS 2.61 1.27 2.34 1.14 0.27 2.3 1.1-3.4 CB74 2Cg5, 142-174 cm VS 0.80 0.39 0.82 0.38 0.00 0.0 0.0-0.3 CB79 A1, 0-3 cm - - - 4.38 - - 3.47 CB79 A2, 3-10 cm VE 7.21 0.79 1.54 0.17 5.67 47.2 46.5-48.0 CB79 Cg1, 10-50 cm VS 3.67 1.94 3.40 1.80 0.27 2.2 0.6-3.9 CB79 Cg2, 50-86 cm VS 2.81 1.55 2.54 1.40 0.27 2.3 1.0-3.5 CB79 Cg3, 86-123 cm VS 0.51 0.28 0.49 0.27 0.02 0.2 0.0-0.4 CB81 A1, 0-2 cm - - - 4.47 - - 4.47 CB81 A2, 2-18 cm NE 13.42 1.98 13.42 1.98 CB81 Cg1, 18-154 cm NE 10.49 4.13 10.49 4.13 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 477 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB84 A, 0-6 cm - - - 8.18 - - 7.64 CB84 Cg1, 6-72 cm NE 14.65 6.20 14.65 6.20 CB84 Cg2, 72-138 cm SL 13.37 4.65 9.72 3.38 3.65 30.4 25.6-35.1 CB86 A, 0-3 cm - - - 10.61 - - 10.61 CB86 Cg1, 3-35 cm NE 18.59 5.09 18.59 5.09 CB86 Cg2, 35-93 cm NE 15.26 4.21 15.26 4.21 CB86 Cg3, 93-105 cm NE 22.77 2.24 22.77 2.24 CB90 A, 0-2 cm - - - 14.50 - - 14.18 CB90 Cg1, 2-32 cm VS 16.87 6.05 16.44 5.90 0.43 3.6 0.0-11.6 CB90 Cg2, 32-42 cm NE 21.71 1.72 21.71 1.72 CB90 Cg3, 42-72 cm VS 18.63 2.99 18.13 2.91 0.40 4.2 0.0-13.0 CB90 Cg4, 72-95 cm VS 12.20 3.36 11.97 3.29 0.23 2.0 0.0-7.8 CB90 Cg5, 95-114 cm VS 10.97 1.45 10.21 1.35 0.76 6.3 1.4-11.3 CB91 A, 0-3 cm - - - 6.11 - - 5.81 CB91 Cg1, 3-54 cm VS 10.24 3.79 9.82 3.63 0.42 3.5 0.0-8.2 CB91 Cg2, 54-61 cm VS 6.73 0.59 6.44 0.56 0.29 2.5 0.0-5.6 CB91 Cg3, 61-139 cm VS 12.10 3.47 11.27 3.23 0.83 6.9 1.4-12.4 CB91 Cg4, 139-169 cm SL 10.27 1.39 9.17 1.24 1.10 9.2 4.7-13.7 CB91 Cg5, 169-191 cm VE 8.55 1.22 5.12 0.73 3.43 28.6 26.1-31.1 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 478 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB93 A1, 0-4 cm - - - 10.00 - - 9.74 CB93 A2, 4-15 cm VS 14.54 1.78 14.06 1.72 0.48 4.0 0.0-10.8 CB93 Cg1, 15-42 cm VS 9.95 3.96 9.75 3.88 0.20 1.7 0.0-6.4 CB93 Cg2, 42-81 cm VS 14.04 3.65 13.71 3.57 0.33 2.7 0.0-9.4 CB93 Cg3, 81-210 cm VS 11.73 4.17 11.04 3.93 0.69 5.7 0.3-11.1 CB94 A1, 0-1 cm - - - 11.12 - - 10.71 CB94 A2, 1-12 cm VS 1.41 0.22 1.22 0.19 0.19 1.5 0.9-2.1 CB94 2Cg1, 12-33 cm VS 15.88 2.28 15.88 2.28 0.00 0.0 0.0-7.8 CB94 2Cg2, 33-94 cm VS 16.19 7.54 16.13 7.51 0.06 0.5 0.0-8.4 CB94 2Cg3, 94-107 cm VE 20.78 2.35 14.04 1.59 6.74 56.2 49.4-63.0 CB94 2Cg4, 107-145 cm VS 15.11 3.73 15.06 3.72 0.05 0.4 0.0-7.7 CB97 A, 0-2 cm - - - 5.75 - - 5.75 CB97 Cg1, 2-76 cm NE 10.69 4.31 10.69 4.31 CB97 Cg2, 76-95 cm NE 11.04 1.28 11.04 1.28 CB97 Cg3, 95-131 cm NE 13.32 3.21 13.32 3.21 CB97 Cg4, 131-145 cm NE 19.63 1.96 19.63 1.96 CB97 Cg5, 145-168 cm SL 37.84 3.70 38.03 3.72 0.00 0.0 0.0-17.0 CB97 Oab/Cg, 168-195 cm NE 42.48 7.64 42.48 7.64 CB97 Oab1, 195-213 cm NE 162.40 6.05 162.40 6.05 CB97 Oab2, 213-224 cm NE 111.50 2.54 111.50 2.54 CB97 Ab, 224-245 cm NE 28.76 3.97 28.76 3.97 CB97 Cgb1, 245-260 cm NE 3.33 0.45 3.33 0.45 CB97 Cgb2, 260-266 cm NE 2.48 0.10 2.48 0.10 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 479 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB100 A, 0-3 cm - - - 9.94 - - 9.35 CB100 Cg1, 3-53 cm VS 14.05 4.80 13.77 4.70 0.28 2.3 0.0-9.0 CB100 Cg2, 53-80 cm SL 10.58 2.70 10.02 2.56 0.56 4.6 0.0-9.5 CB100 Ab, 80-100 cm ST 14.87 2.45 12.68 2.09 2.19 18.3 12.1-24.5 CB106 A1, 0-3 cm - - - 12.67 - - 11.81 CB106 A2, 3-16 cm SL 8.72 2.12 7.92 1.93 0.80 6.7 2.8-10.5 CB106 Cg1, 16-53 cm SL 10.75 4.28 9.02 3.59 1.73 14.5 10.1-18.8 CB106 Cg2, 53-69 cm VS 20.58 5.29 20.58 5.29 0.00 0.0 0.0-11.6 CB106 Cg3, 69-165 cm VS 32.14 3.11 32.89 3.04 0.00 0.0 0.0-9.8 CB111 A1, 0-3 cm - - - 6.42 - - 6.18 CB111 A2, 3-20 cm VS 17.88 1.92 17.43 1.87 0.45 3.7 0.0-12.2 CB111 Cg1, 20-42 cm NE 13.13 2.32 13.13 2.32 CB111 Cg2, 42-200 cm VS 14.30 5.93 13.07 5.42 1.23 10.2 3.9-16.6 CB117 A, 0-16 cm VS 24.30 4.39 10.92 5.29 0.96 6.93 19.01 158.4 155.8-160.9 CB117 Cg1,16-34 cm ST 13.08 2.65 9.96 2.02 3.12 26.0 21.2-30.8 CB117 Cg2, 34-97 cm SL 11.15 3.71 9.83 3.27 1.32 11.0 6.2-15.8 CB117 Cg3, 97-163 cm SL 8.33 3.73 7.29 3.27 1.04 8.7 5.1-12.2 CB118 A, 0-9 cm VS 15.06 1.56 6.80 14.53 1.51 6.43 0.53 4.4 0.0-11.5 CB118 Cg1, 9-19 cm VS 14.01 1.01 13.42 0.79 0.59 4.8 0.0-11.4 CB118 Cg2, 19-117 cm SL 10.40 5.12 9.74 4.79 0.66 5.5 0.7-10.2 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 480 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB119 A, 0-17 cm VS 14.43 1.77 5.54 14.34 1.75 8.43 0.09 0.7 0.0-7.7 CB119 Cg1, 17-44 cm VS 11.85 2.92 11.50 2.83 0.35 3.0 0.0-8.6 CB119 Cg2, 44-73 cm VS 9.33 2.53 8.80 2.39 0.53 4.4 0.1-8.7 CB119 Cg3, 73-99 cm NE 4.21 1.46 4.21 1.46 CB120 A, 0-12 cm VS 15.90 0.39 9.03 15.57 0.39 5.45 0.33 2.8 0.0-10.4 CB120 Cg1, 12-31 cm NE 11.90 1.79 11.90 1.79 CB120 2Cg2, 31-56 cm VS 9.89 2.15 9.67 2.10 0.22 1.8 0.0-6.5 CB120 2Cg3, 56-81 cm VS 2.01 0.69 1.98 0.68 0.03 0.2 0.0-1.2 CB120 2Cg4, 81-102 cm VS 2.20 0.57 2.12 0.55 0.08 0.7 0.0-1.7 CB121 A, 0-12 cm VS 23.60 1.73 16.92 23.48 1.72 9.05 0.12 1.0 0.0-12.5 CB121 Cg1, 12-52 cm VS 14.83 2.80 14.85 2.80 0.00 0.0 0.0-7.0 CB121 Cg2, 52-89 cm NE 14.00 3.38 14.00 3.38 CB121 Cg3, 89-197 cm VS 22.40 10.99 22.04 11.17 0.00 0.0 0.0-7.9 CB124 A, 0-6 cm VS 1.07 0.08 16.92 0.93 0.07 16.84 0.14 1.2 0.7-1.6 CB124 Cg1, 6-48 cm VS 0.88 0.50 0.75 0.42 0.13 1.1 0.7-1.4 CB124 2Cg2, 48-70 cm NE 36.43 4.04 36.43 4.04 CB124 2Oab1, 70-116 cm NE 186.75 18.87 186.75 18.87 CB124 2Oab2, 116-130 cm NE 189.50 7.69 189.50 7.69 CB124 3Ab, 130-136 cm NE 32.38 2.23 32.38 2.23 CB124 3Cgb, 136-157 cm NE 11.39 2.84 11.39 2.84 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 481 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB127 A, 0-22 cm VS 12.99 3.50 9.14 12.40 3.34 8.91 0.59 5.0 0.0-11.0 CB127 Cg1, 22-51 cm VS 12.55 1.97 12.60 1.96 0.00 0.0 0.0-5.6 CB127 Cg2, 51-102 cm VS 9.99 3.82 9.78 3.74 0.21 1.7 0.0-6.5 CB130 A1, 0-4 cm - - - 9.56 - - 9.30 CB130 A2, 4-21 cm VS 17.18 1.48 16.76 1.45 0.42 3.5 0.0-11.6 CB130 Cg1, 21-58 cm VS 9.60 3.31 9.31 3.21 0.29 2.5 0.0-7.0 CB130 Cg2, 58-125 cm VS 10.25 7.60 9.98 7.40 0.27 2.2 0.0-7.1 CB130 Cg2, 125-199 cm VS 10.74 6.51 10.53 6.38 0.21 1.7 0.0-6.9 CB130 Cg3, 199-275 cm SL 9.62 7.45 8.98 6.96 0.64 5.3 1.0-9.7 CB130 Cg3, 275-340 cm VS 11.94 6.67 11.51 6.43 0.43 3.5 0.0-9.1 CB136 A1, 0-2 cm - - - 7.71 - - 7.41 CB136 A2, 2-18 cm VS 3.13 0.08 2.89 0.07 0.24 2.0 0.6-3.4 CB136 Cg1, 18-37 cm VS 10.32 2.77 10.13 2.72 0.19 1.6 0.0-6.5 CB136 2Cg2, 37-93 cm SL 11.98 4.43 11.36 4.21 0.32 5.1 0.0-10.6 CB136 2Cg3, 93-146 cm VS 10.91 6.14 10.38 5.85 0.53 4.4 0.0-9.4 CB136 2Cg4, 146-161 cm NE 53.57 3.96 53.57 3.96 CB136 2Oab1, 161-187 cm NE 271.70 15.52 271.70 15.52 CB136 2Oab2, 187-205 cm NE 164.25 6.50 164.25 6.50 CB136 3Ab, 205-211 cm NE 44.63 1.76 44.63 1.76 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 482 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 CB141 A1, 0-4 cm - - - 17.26 - - 6.67 CB141 A2, 4-13 VE 17.75 1.12 5.30 0.33 12.45 103.7 101.1-106.3 CB141 Cg1, 13-23 cm VE 51.07 5.06 6.67 0.66 44.40 370.0 366.7-373.2 CB141 Cg2, 23-46 cm VE 33.34 6.78 8.58 1.74 24.76 206.3 202.1-210.5 CB141 Cg3, 46-123 cm SL 13.04 6.14 11.89 5.60 1.15 9.6 3.8-15.4 CB141 Cg4, 123-174 cm VS 14.83 5.64 13.45 5.12 1.38 11.5 5.0-18.0 CB142 A, 0-3 cm - - - 8.91 - - 8.49 CB142 Cg1, 3-36 cm VS 12.55 4.00 11.87 3.78 0.68 5.6 0.0-11.4 CB142 Cg2, 36-100 cm SL 14.34 4.92 13.74 4.71 0.60 5.0 0.0-11.7 CB142 Oab, 100-131 cm NE 230.70 15.71 230.70 15.71 CB142 Ab, 131-134 cm NE 46.04 1.19 46.04 1.19 CB142 BAgb, 134-142 cm NE 21.73 2.70 21.73 2.70 CB142 Cgb, 142-149 cm NE 5.87 0.91 5.87 0.91 CB143 A, 0-3 cm - - - 8.84 - - 8.84 CB143 Cg1, 3-61 cm NE 13.98 5.39 13.98 5.39 CB143 Cg2, 61-95 cm NE 8.60 2.25 8.60 2.25 CB143 Cg3, 95-108 cm NE 12.44 3.13 12.44 3.13 CB143 2Cg4, 108-137 cm VS 2.53 0.78 2.63 0.77 0.00 0.0 0.0-0.4 CB144 A, 0-29 cm VS 16.17 3.21 10.85 15.88 3.15 10.59 0.29 2.4 0.0-10.2 CB144 Cg1, 29-51 cm VS 19.47 3.78 18.67 3.63 0.80 6.6 0.0-15.7 CB144 2Cg2, 51-75 cm VS 17.11 2.57 16.80 2.53 0.31 2.6 0.0-10.7 CB144 2Cg3, 75-104 cm NE 6.01 1.49 6.01 1.49 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 483 Appendix D: Continued. Pedon Sample Effervescence Total C Organic C CO 3 -C Calcium Carbonate g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 kg m -2 kg m -2 upper 1 m g kg -1 Avg. g kg -1 ?2 sd * g kg -1 M06 Oab NE 212.00 M08 Oab, 200 cm NE 220.94 M08 Oab, 230 cm NE 182.33 M10 Oab1 NE 107.10 M10 Oab2 NE 221.16 M10 Oab3 NE 304.87 * Range in calcium carbonate calculated due to uncertainty in the amount of organic carbon oxidized by H 2 SO 3 treatment. 484 Appendix E: Moist Incubation pH Data 485 pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 CB01 A, 0-14 None 6.28 6.00 4.81 5.12 6.11 5.26 6.38 6.12 5.85 6.20 5.30 4.81 CB01 Cg1, 14-76 Strong 6.61 5.27 3.89 3.57 3.00 3.10 3.28 3.25 3.36 3.33 3.39 3.31 CB01 Cg2, 76-103 Strong 6.87 5.97 3.99 3.79 3.32 3.03 3.03 2.95 3.00 2.96 3.04 3.07 CB01 Cg3, 103-170 Strong 7.12 6.60 5.23 5.07 5.37 4.35 3.86 3.65 3.50 3.10 2.99 2.86 CB01 Cg4, 170-210 Strong 7.48 6.65 5.35 5.29 4.85 3.75 3.41 3.12 2.99 2.58 2.76 2.80 CB04 A, 0-6 --- --- --- --- --- --- --- --- --- --- --- --- --- CB04 Cg1, 6-32 Strong 6.47 6.49 5.78 6.13 5.65 4.47 3.59 3.55 3.33 2.96 2.97 2.70 CB04 Cg2, 32-111 Strong 7.55 7.13 6.26 7.41 7.11 7.37 7.29 7.08 7.00 6.31 6.71 5.75 CB04 Cg3, 111- 149 Strong 7.45 7.15 6.54 6.24 4.75 3.69 2.97 3.09 2.93 2.55 2.48 2.51 CB10 A, 0-17 Strong 7.26 6.30 5.37 4.41 3.45 3.40 3.56 3.54 3.52 3.56 3.59 3.44 CB10 Cg1, 17-51 Strong 7.10 3.92 3.60 3.09 2.93 2.79 2.79 2.71 2.87 2.84 3.04 2.98 CB10 Cg2, 51-64 Strong 6.48 6.14 4.34 4.84 4.18 3.66 2.97 2.84 2.71 2.55 2.70 2.80 CB10 2Cg3, 64-84 Strong 6.84 6.80 5.89 5.57 4.82 4.45 3.26 3.22 3.08 2.74 2.72 2.73 CB10 3Cg4, 84-89 Strong 6.88 6.83 5.96 5.88 5.44 4.60 4.34 3.82 3.50 2.95 3.81 3.58 CB10 3Cg5, 89-134 Strong 7.32 7.07 6.31 6.74 6.86 6.37 6.75 6.82 6.48 6.03 6.66 6.01 CB11 A1, 0-2 Strong --- --- --- --- --- --- --- --- --- --- --- --- CB11 A2, 2-12 Strong 7.65 6.85 6.55 6.71 6.80 6.57 5.38 5.65 5.29 3.69 3.22 3.05 CB11 Cg1, 12-36 Strong 7.51 6.59 6.35 5.40 4.06 3.63 3.04 2.96 2.68 2.37 2.43 2.61 CB11 Cg2, 36-56 Strong 6.47 6.61 6.18 4.89 4.27 3.44 3.05 2.97 2.88 2.60 2.58 2.53 CB11 Oab1, 56-83 Strong 6.70 6.21 4.88 3.67 3.26 3.04 2.69 2.72 2.74 2.36 2.36 2.30 CB11 Oab2, 83-109 Strong 7.00 6.38 5.48 5.23 4.89 4.63 3.62 3.29 3.17 2.90 2.71 2.61 CB11 2Ab, 109-115 Strong 6.91 7.01 6.11 6.39 6.39 6.44 6.28 6.10 5.63 5.39 5.46 5.19 CB11 2Cgb, 115-122 Strong 7.00 7.04 6.76 6.82 7.00 6.75 7.08 6.98 6.60 6.68 6.72 6.15 CB16 A1, 0-2 --- --- --- --- --- --- --- --- --- --- --- --- --- CB16 A2, 2-22 Strong 6.58 5.06 6.19 4.80 3.81 3.30 3.25 3.27 3.28 3.39 3.51 3.43 CB16 Cg1, 22-37 Strong 6.69 5.67 6.25 5.78 5.63 4.75 3.98 3.60 3.16 2.90 3.03 3.12 CB16 Cg2, 37-67 Strong 6.93 6.23 5.94 4.69 4.57 4.04 3.47 3.42 3.12 2.95 2.78 2.76 CB16 Cg3, 67- 80 Strong 7.00 6.12 6.02 4.79 4.16 3.99 3.44 3.38 3.21 2.79 3.00 3.09 CB16 Cg4, 80-114 Strong 7.16 6.21 6.15 5.22 5.89 5.07 4.07 3.98 3.76 3.48 3.62 3.61 CB16 Cg5, 114-187 Strong 7.29 6.97 6.18 5.85 6.40 5.81 4.61 4.72 4.33 3.61 3.59 3.31 CB16 Cg6, 187-215 Strong 7.38 7.33 6.14 6.14 6.49 5.96 4.63 4.74 3.80 3.21 3.22 3.27 486 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 CB17 A, 0-8 None 7.28 7.06 6.34 6.42 6.23 6.31 5.79 5.79 5.22 4.78 4.45 4.30 CB17 Cg/A, 8-32 Strong 7.27 6.77 5.86 5.35 4.96 4.57 3.35 3.31 3.25 3.09 2.98 2.91 CB17 Cg1, 32-54 Strong 7.36 6.76 6.35 6.47 6.19 5.81 5.36 5.10 5.18 3.74 3.32 3.00 CB17 Cg2, 54-77 Strong 7.51 6.79 5.66 4.00 3.31 3.30 2.95 2.94 2.85 2.72 2.66 2.57 CB17 Cg3, 77-102 Strong 7.09 4.12 4.27 2.72 2.61 2.68 2.81 2.70 2.85 3.11 3.20 3.29 CB17 Cg4, 102-148 Strong 6.54 3.91 3.84 2.96 2.53 2.69 2.67 2.76 2.70 2.79 2.77 3.03 CB18 A, 0-8 None --- --- --- --- --- --- --- --- --- --- --- --- CB18 Cg, 8-50 Strong 7.08 6.55 5.73 6.45 6.37 5.80 5.63 5.17 5.00 4.17 4.17 3.21 CB18 Cg, 50-100 Strong 7.66 7.00 6.74 7.33 6.91 6.72 7.07 6.90 6.29 6.09 6.09 3.16 CB18 Cg, 100-150 Strong 7.77 7.70 6.97 7.37 7.21 7.03 7.17 6.83 6.33 6.28 6.28 4.76 CB18 Cg, 150-200 Strong 7.93 7.89 7.06 6.99 7.13 6.91 6.26 5.99 5.19 3.92 3.92 3.13 CB18 Cg, 200-250 Strong 7.94 7.87 7.08 7.47 7.20 6.97 6.94 7.09 5.80 3.75 3.75 2.89 CB26 A, 0-2 Strong --- --- --- --- --- --- --- --- --- --- --- --- CB26 Cg, 2-28 Strong 7.45 6.89 4.00 2.98 2.69 2.56 2.62 2.61 2.71 2.76 2.77 2.78 CB26 A?, 28-50 Strong 5.38 4.95 3.65 3.11 2.94 2.92 2.69 2.75 2.66 2.43 2.42 2.43 CB26 C?g, 50-70 Strong 7.10 6.32 4.36 3.74 3.34 2.88 2.66 2.54 2.41 2.24 2.27 2.43 CB26 Cg/Oa, 70-103 Strong 7.34 6.22 5.29 5.37 5.08 3.92 3.28 3.09 2.90 2.53 2.50 2.43 CB26 Oab, 103-132 Strong 7.03 6.33 5.27 4.97 4.25 3.38 2.63 2.62 2.53 2.30 2.35 2.29 CB26 Ab, 132-137 Strong 6.77 6.43 5.65 5.85 5.69 5.20 4.62 4.50 4.27 3.70 3.50 3.34 CB26 Btgb, 137-150 Strong 6.87 6.63 5.67 4.97 4.63 4.28 3.20 3.12 3.19 3.03 3.06 3.04 487 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 WK 16 WK 18 WK 20 WK 22 WK 25 CB09 A1, 0-2 None CB09 A2, 2-16 None 7.32 6.65 6.52 6.38 6.43 6.06 5.90 6.42 6.04 5.77 5.56 5.02 4.37 3.51 3.34 --- --- CB09 Cg1, 16-22 None 6.85 6.50 5.44 4.15 3.79 3.84 3.63 3.61 3.34 3.30 2.40 2.53 2.53 --- --- --- --- CB09 Cg2, 22-42 None 6.28 6.33 5.00 4.11 3.45 3.56 3.26 3.16 2.65 2.68 2.55 2.45 2.43 --- --- --- --- CB09 Cg/Bgb, 42-53 None 6.35 6.32 5.51 4.80 4.17 4.01 3.74 3.56 3.05 3.10 2.42 2.50 2.43 --- --- --- --- CB09 2Bgb, 53-76 None 5.90 6.04 5.55 4.97 4.33 4.16 4.03 3.77 2.91 3.15 2.65 2.73 2.89 --- --- --- --- CB09 2Bwb1, 76-98 None 5.92 6.08 5.81 5.36 5.45 5.24 5.15 5.21 5.55 5.57 5.46 5.49 5.36 5.36 5.38 5.21 5.38 CB09 2Bwb2, 98-108 None 5.61 5.92 6.03 5.62 5.57 5.58 5.34 5.55 5.45 5.47 5.40 5.51 5.43 5.31 5.32 5.30 5.37 CB09 2BCgb, 108-118 None 5.58 6.22 5.95 5.21 5.45 5.69 5.23 5.54 5.49 5.56 5.48 5.59 5.57 5.62 5.43 5.42 5.57 CB09 2Cgb1, 118-133 None 5.47 5.94 5.93 5.56 5.74 5.71 5.29 5.58 5.29 5.35 5.32 5.42 5.32 5.47 5.37 5.36 5.48 CB09 2Cgb2, 133-151 None 5.67 6.07 6.12 5.96 5.91 5.82 5.71 5.89 5.59 5.59 5.61 5.60 5.47 5.51 5.54 5.41 5.43 CB21 A1, 0-2 None 7.18 7.15 7.03 6.45 6.97 6.67 6.76 7.11 7.16 7.01 6.83 6.86 6.61 6.61 6.38 5.92 5.55 CB21 A2, 2-18 None 7.39 6.88 6.71 6.05 6.47 6.14 6.14 6.49 6.47 6.04 5.70 5.22 4.48 4.24 3.36 3.18 CB21 Oa, 18-58 Weak --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB21 Ab, 58-62 None 6.98 7.29 6.75 6.24 5.19 4.86 4.22 3.78 3.70 2.72 2.23 2.16 2.09 --- --- --- --- CB21 BAgb, 62-71 None 7.31 7.52 6.58 5.65 5.07 4.29 3.87 3.45 3.14 3.06 2.39 2.48 2.34 --- --- --- --- CB21 Btgb, 71-96 None 7.22 7.32 6.76 5.42 5.05 3.98 3.56 3.33 3.26 2.86 2.54 2.47 2.49 --- --- --- --- CB21 2Cgb, 96-134 None 7.96 7.42 6.70 5.61 4.92 4.43 4.10 3.79 3.32 3.30 3.41 3.39 3.55 --- --- --- --- CB24 Oa/Cg, 22-50 Strong 7.25 6.94 6.33 5.51 5.20 4.71 4.50 4.36 4.20 3.74 2.76 2.56 CB24 Cg/Oa, 50-71 Strong 7.26 7.14 5.80 4.60 4.34 3.81 3.65 3.54 3.16 2.41 2.39 2.44 CB39 A1, 0-1 Weak --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB39 A2, 1-12 None 7.50 7.72 7.63 7.06 6.79 6.17 6.01 7.21 7.00 7.00 6.88 6.41 5.85 5.59 5.27 5.02 4.08 CB39 Cg1, 12-43 None 7.98 8.11 7.70 7.07 6.98 6.60 6.35 7.22 7.23 6.94 6.73 6.24 5.33 4.84 4.29 3.67 2.93 CB39 Cg2, 43-57 None 8.14 7.98 7.53 7.05 7.03 6.62 6.50 7.02 7.02 6.65 5.83 4.89 3.85 --- --- --- --- CB39 Cg3, 57-126 None 7.89 8.02 7.02 6.51 6.10 5.51 4.67 4.34 3.86 3.65 2.68 2.35 2.29 --- --- --- --- CB39 2Cg4, 126-161 None 6.46 6.86 6.57 5.47 4.10 4.07 3.58 3.62 3.23 2.85 2.30 2.50 2.40 --- --- --- --- CB39 2Cg5, 161-198 None 6.41 6.95 6.33 5.37 3.89 3.84 3.67 3.72 3.38 3.25 2.59 2.92 2.69 --- --- --- --- 488 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 WK 16 WK 18 WK 20 WK 22 WK 25 CB45 A, 0-6 Strong 7.30 6.68 6.26 5.40 4.59 4.40 4.28 4.44 4.28 4.08 3.58 3.53 3.79 --- --- --- --- CB45 Cg/A, 6-33 Strong 7.57 6.54 5.46 4.28 3.54 3.79 3.72 3.85 3.04 3.02 3.24 3.31 3.45 --- --- --- --- CB45 Cg1, 33-88 Strong 7.95 6.64 4.38 3.81 3.04 3.51 3.41 3.49 2.62 2.66 2.68 2.85 2.88 --- --- --- --- CB45 Cg2, 88-99 Strong 8.06 7.96 6.02 5.46 4.13 5.08 4.60 4.81 4.50 4.22 2.46 2.68 2.83 --- --- --- --- CB45 2Cg3, 99-142 Strong 8.10 8.25 7.52 6.57 6.03 6.22 6.20 6.87 6.69 6.13 5.12 4.19 2.73 --- --- --- --- CB45 2Cg4, 142-186 Strong 8.33 8.53 7.98 7.29 6.96 6.73 6.87 7.29 7.02 6.53 5.88 4.89 3.72 --- --- --- --- CB50 A1, 0-3 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB50 A2, 3-21 None 7.86 7.72 8.15 7.46 7.14 7.10 7.25 7.99 7.96 7.98 7.95 7.88 8.00 7.92 8.03 7.97 7.91 CB50 Cg/A, 21-45 None 7.83 8.06 8.00 7.68 7.36 7.29 6.98 7.62 8.02 7.95 7.85 7.89 8.07 7.96 8.06 7.90 7.89 CB50 Cg1, 45-60 None 7.80 8.24 7.99 7.56 7.35 7.33 7.17 7.75 7.39 7.78 7.71 7.83 7.81 7.66 7.88 7.96 7.92 CB50 Cg2, 60-92 Strong 7.74 8.03 7.95 7.59 7.12 7.09 6.92 6.83 6.60 6.18 6.20 5.14 4.37 3.61 2.87 --- --- CB50 Cg3, 92-160 Strong 8.15 8.40 7.79 7.53 6.69 7.13 6.87 6.87 6.76 6.57 6.19 5.96 5.45 5.49 5.09 4.43 3.45 CB52 A1 & A2 0-10 Strong 7.50 7.38 6.54 5.96 6.76 7.12 6.91 6.84 6.75 6.47 6.14 5.68 4.66 4.38 4.13 4.01 3.70 CB52 Cg1, 10-21 Strong 7.78 7.76 6.88 6.36 6.30 6.28 5.82 5.25 4.68 4.41 2.92 2.54 2.63 --- --- --- --- CB52 2Cg2, 21-39 Strong 7.58 7.84 7.14 6.46 6.34 5.65 5.28 4.92 4.73 4.21 2.88 2.63 2.60 --- --- --- --- CB52 2Cg3, 39-59 Strong 7.62 7.83 7.08 6.44 6.20 4.77 4.58 4.58 4.67 3.86 3.03 2.99 3.03 --- --- --- --- CB52 2Cg4, 59-86 Strong 7.60 7.99 7.10 6.35 6.23 4.89 4.61 4.54 4.43 4.21 3.21 2.81 2.80 --- --- --- --- CB52 2Cg5, 86-115 Strong 7.68 8.22 7.58 6.83 6.69 6.24 6.07 6.69 6.40 6.30 5.59 4.99 3.60 --- --- --- --- CB52 2Cg6, 115-138 Strong 7.65 7.85 7.53 7.09 7.02 6.61 6.55 7.37 7.09 7.06 6.81 6.62 6.32 5.86 5.41 4.94 4.15 CB56 A1, 0-2 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB56 A2, 2-10 Strong 7.67 7.68 7.07 6.51 4.50 4.53 4.37 4.21 3.74 3.56 2.64 2.87 3.01 --- --- --- --- CB56 Cg1, 10-31 Strong 7.88 7.56 6.53 5.46 4.30 4.15 4.08 4.05 3.72 3.54 2.64 2.89 3.03 --- --- --- --- CB56 Cg2, 31-49 Strong 7.66 7.61 7.36 6.58 7.38 6.79 6.85 8.08 7.76 8.13 7.79 7.78 7.78 7.81 7.83 7.49 7.74 CB56 Cg3, 49-72 Strong 7.74 8.08 7.32 6.32 4.55 3.91 3.87 3.83 3.85 3.78 2.54 2.73 2.80 --- --- --- --- CB56 Cg4, 72-90 Strong 7.82 8.12 7.23 5.67 3.89 3.66 3.67 3.65 3.50 3.44 2.34 2.53 2.55 --- --- --- --- CB56 Cg5, 90-122 Strong 8.26 8.23 6.43 4.92 3.86 3.87 3.90 3.86 3.62 3.64 2.67 2.74 2.92 --- --- --- --- CB56 Cg6, 122-137 Strong 7.40 8.48 7.45 7.23 7.29 7.41 7.35 7.93 7.84 8.09 7.69 7.68 7.87 7.92 8.02 7.92 7.86 CB56 2Ab, 137-154 Strong 7.73 8.12 7.88 7.34 7.37 7.37 7.38 7.68 7.53 7.62 7.36 7.31 7.15 6.97 7.12 7.28 7.07 489 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 WK 16 WK 18 WK 20 WK 22 WK 25 CB58 A1, 0-3 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB58 A2, 3-14 Strong 7.72 7.91 7.96 7.41 7.51 7.41 7.42 7.68 7.62 7.69 7.60 7.63 7.61 7.58 7.81 7.73 7.59 CB58 Cg1, 14-37 Strong 7.90 8.09 7.78 7.38 6.28 7.11 7.10 6.66 6.71 6.07 6.15 5.34 3.75 --- --- --- --- CB58 Cg2, 37-106 Strong 7.58 7.91 7.79 7.36 6.70 6.43 6.45 6.81 6.62 5.88 6.29 6.03 5.10 4.24 3.66 3.11 --- CB58 2Cg3, 106-162 Strong 7.54 7.82 7.81 7.25 6.90 6.71 6.62 6.51 6.36 5.92 5.18 4.28 3.12 --- --- --- --- CB74 A1, 0-2 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB74 A2, 2-19 None 7.56 6.64 7.61 6.95 5.53 5.26 4.91 4.65 4.33 4.10 3.15 2.56 2.70 --- --- --- --- CB74 Cg1, 19-55 None 7.66 6.39 6.36 5.88 4.35 4.09 3.96 3.91 3.51 3.29 2.40 2.48 2.50 --- --- --- --- CB74 Cg2, 55-89 None 7.63 6.92 5.74 4.60 3.46 3.56 3.56 3.47 3.26 2.66 2.41 2.49 2.56 --- --- --- --- CB74 Cg3, 89-109 Weak 7.50 7.22 5.96 4.38 3.96 3.53 3.38 3.29 3.20 3.12 2.61 2.38 2.40 --- --- --- --- CB74 2Cg4, 109-142 Weak 7.53 7.59 7.09 6.60 6.65 7.20 7.20 7.89 7.75 8.03 7.96 7.88 7.80 7.98 8.03 7.97 8.24 CB74 2Cg5, 142-174 None 7.61 7.56 5.43 3.78 3.04 3.75 3.55 3.57 3.47 3.46 3.41 3.38 3.42 --- --- --- --- CB79 A1, 0-3 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB79 A2, 3-10 None 7.73 7.60 6.65 6.31 6.58 6.59 6.75 8.17 7.83 8.18 7.85 7.99 8.00 8.06 8.05 7.96 8.03 CB79 Cg1, 10-50 Strong 7.65 7.96 6.87 6.37 6.61 6.46 6.27 6.17 5.52 4.86 4.20 3.63 3.20 --- --- --- --- CB79 Cg2, 50-86 Strong 7.82 8.08 6.86 6.68 6.70 6.52 6.54 6.86 6.60 6.20 5.69 5.19 4.82 4.33 3.40 2.88 --- CB79 Cg3, 86-123 Strong 8.04 7.16 6.98 6.60 6.58 6.53 6.45 6.38 5.53 5.10 4.15 3.69 3.49 CB91 A, 0-3 Weak --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB91 Cg1, 3-54 Weak 7.59 8.06 7.48 7.03 7.16 6.85 6.81 7.04 6.88 6.61 6.18 5.64 4.87 4.12 3.22 3.00 --- CB91 Cg2, 54-61 None 7.73 8.17 7.49 7.07 6.35 6.74 6.75 6.87 6.19 5.20 3.92 2.98 2.57 --- --- --- --- CB91 Cg3, 61-139 Weak 7.58 8.31 7.62 7.11 7.03 6.82 6.54 6.98 6.82 6.45 6.25 5.25 4.23 3.87 3.08 --- --- CB91 Cg4, 139-169 None 7.35 8.27 7.49 7.12 7.06 6.73 6.52 6.58 6.61 5.38 5.25 4.00 3.29 --- --- --- --- CB91 Cg5, 169-191 Weak 7.30 8.11 7.73 7.50 5.00 4.47 3.90 3.45 3.52 3.18 3.09 2.77 2.47 --- --- --- --- CB94 A1, 0-1 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB94 A2, 1-12 None 7.21 7.17 5.96 5.49 3.99 3.97 4.15 4.08 4.16 3.97 3.67 3.70 3.87 --- --- --- --- CB94 2Cg1, 12-33 Strong 7.34 7.20 6.12 5.43 4.42 3.74 3.35 3.33 3.30 3.19 3.08 2.51 2.43 --- --- --- --- CB94 2Cg2, 33-94 Strong 7.54 7.52 6.40 5.58 4.62 3.94 3.60 3.59 3.45 3.32 2.77 2.43 2.39 --- --- --- --- CB94 2Cg3, 94-107 Strong 7.56 7.82 7.14 6.60 6.77 6.58 6.57 7.16 7.25 7.32 7.16 7.14 6.54 6.59 6.25 6.25 5.31 CB94 2Cg4, 107-145 Strong 7.50 7.96 6.06 6.21 4.64 3.72 3.43 3.27 3.36 3.12 2.75 2.49 2.39 --- --- --- --- 490 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 WK 16 WK 18 WK 20 WK 22 WK 25 CB97 A, 0-2 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB97 Cg1, 2-76 Strong 7.59 8.23 6.72 5.88 6.32 6.19 6.23 6.85 6.71 6.39 5.04 3.99 2.70 --- --- --- --- CB97 Cg2, 76-95 Strong 7.79 8.38 7.14 6.57 6.72 6.39 6.38 6.61 6.53 5.76 4.81 4.16 2.85 --- --- --- --- CB97 Cg3, 95-131 Strong 7.51 7.90 7.27 6.81 6.93 6.39 6.34 6.13 6.42 5.29 5.59 3.69 3.03 --- --- --- --- CB97 Cg4, 131-145 Strong 7.62 8.36 7.20 6.75 6.74 5.93 5.60 5.21 4.95 4.37 4.14 3.11 2.71 --- --- --- --- CB97 Cg5, 145-168 Strong 7.35 8.31 7.22 6.64 5.56 5.55 5.30 5.01 4.84 4.65 4.10 3.28 2.94 --- --- --- --- CB97 Oa/Cg, 168-195 Strong 7.47 8.34 7.07 6.31 4.99 4.58 4.27 4.08 3.77 3.36 2.90 2.69 2.56 --- --- --- --- CB97 Oab1, 195-213 Strong 7.64 7.70 6.91 5.68 4.98 4.21 4.04 3.91 3.88 3.43 2.60 2.46 2.30 --- --- --- --- CB97 Oab2, 213-224 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB97 2Ab, 224-245 Strong 6.87 7.29 6.77 5.95 4.93 5.95 3.53 3.19 3.01 2.78 2.51 2.37 2.25 --- --- --- --- CB97 2Cgb1, 245-260 None 6.76 7.39 5.65 4.14 3.07 3.87 2.85 2.66 2.77 2.40 2.46 2.31 2.33 --- --- --- --- CB97 2Cgb2, 260-266 None 6.38 7.31 5.67 4.30 3.69 3.05 2.99 2.85 2.78 2.40 2.52 2.25 2.10 --- --- --- --- CB124 A, 0-6 None 7.67 7.23 6.68 5.48 5.72 5.21 5.70 6.37 6.35 6.05 5.79 5.62 4.51 4.20 4.28 4.56 4.39 CB124 Cg1, 6-48 None 7.80 7.22 6.79 5.87 6.47 6.29 6.58 7.45 7.46 7.68 7.18 7.55 7.61 7.59 7.73 7.08 7.52 CB124 2Cg2, 48-70 Strong 7.49 7.64 6.90 6.10 5.19 4.04 3.40 3.17 3.34 2.85 2.58 2.40 2.36 --- --- --- --- CB124 2Oab1, 70-116 Strong 7.84 7.63 7.26 6.52 5.88 4.36 3.83 3.81 3.89 3.32 2.88 2.62 2.45 --- --- --- --- CB124 2Oab2, 116-130 Strong 7.59 7.84 7.49 6.25 6.31 5.95 5.89 6.01 5.73 5.43 5.22 4.91 4.71 4.60 4.44 4.38 4.13 CB124 3Ab, 130-136 Strong 7.12 7.41 7.55 6.72 5.51 4.90 4.73 4.56 4.25 3.92 3.75 3.28 3.25 --- --- --- --- CB124 3Cgb, 136-157 Strong 7.37 7.82 7.58 6.44 4.68 4.02 3.78 3.60 3.59 3.36 3.03 3.06 3.02 --- --- --- --- CB130 A1, 0-4 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB130 A2, 4-21 None 7.09 7.29 6.67 6.23 6.46 5.88 6.32 7.01 6.94 6.63 6.53 6.22 5.61 5.39 4.99 4.98 4.16 CB130 Cg1, 21-58 None 7.63 7.75 6.98 6.38 6.16 5.64 5.72 5.61 4.69 4.02 3.23 2.55 2.59 --- --- --- --- CB130 Cg2, 58-125 Strong 7.72 8.04 7.25 6.43 6.38 5.75 5.46 5.26 4.45 4.05 3.76 2.86 2.56 --- --- --- --- CB130 Cg2, 125-199 Strong 7.78 8.30 7.62 6.77 6.51 5.90 6.07 6.36 6.23 5.54 4.71 4.11 3.20 --- --- --- --- CB130 Cg3, 199-275 Strong 7.95 8.10 7.76 6.97 6.59 6.51 6.53 6.46 5.89 5.39 4.79 4.12 3.24 --- --- --- --- CB130 Cg3, 275-340 Strong 7.89 8.32 7.38 6.63 6.81 6.16 6.18 6.21 5.79 4.62 3.68 2.91 2.53 --- --- --- --- 491 Appendix E: Continued. pH Pedon Horizon, Depth (cm) Intensity of H 2 S in the field WK 0 WK 1 WK 2 WK 3 WK 4 WK 5 WK 6 WK 7 WK 8 WK 9 WK 11 WK 13 WK 16 WK 18 WK 20 WK 22 WK 25 CB136 A1, 0-2 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB136 A2, 2-18 None 7.80 8.25 7.61 6.91 7.43 6.80 7.45 8.03 7.86 7.90 7.87 7.87 7.96 8.06 8.17 7.94 7.92 CB136 Cg1, 18-37 None 7.61 8.18 7.60 6.79 7.19 6.66 6.40 6.07 5.79 4.57 4.20 2.83 2.52 --- --- --- --- CB136 2Cg2, 37-93 Strong 7.42 7.34 7.64 7.00 7.26 6.69 6.89 6.87 7.02 6.46 6.48 6.17 5.16 4.25 3.43 3.08 --- CB136 2Cg3, 93-146 Strong 7.46 7.77 7.66 6.64 6.12 4.98 4.54 4.12 3.87 3.36 2.50 2.45 2.45 --- --- --- --- CB136 2Cg4, 146-161 Strong 7.44 7.64 6.93 6.48 4.82 3.38 3.31 3.03 3.16 2.96 2.39 2.22 2.21 --- --- --- --- CB136 2Oab1, 161-187 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB136 2Oab2, 187-205 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB136 3Ab, 205-211 Strong 6.93 7.10 6.73 6.27 5.58 4.77 4.45 4.16 4.05 3.45 2.67 2.47 2.46 --- --- --- --- CB141 A1, 0-4 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB141 A2, 4-13 None 7.62 7.72 7.24 6.99 6.96 6.92 7.29 7.96 7.73 7.98 7.72 7.86 7.96 7.88 8.05 7.94 7.98 CB141 Cg1, 13-23 None 7.71 8.06 7.50 7.31 7.19 7.32 7.75 8.00 7.91 8.03 7.80 7.94 7.94 7.96 7.96 8.05 8.10 CB141 Cg2, 23-46 Strong 7.66 8.30 7.74 7.51 7.67 7.37 7.74 8.00 7.86 7.96 7.85 7.94 7.95 7.95 7.89 7.97 7.97 CB141 Cg3, 46-123 Strong 7.62 8.59 8.01 7.62 7.74 7.29 7.27 7.10 6.95 6.74 6.30 5.87 4.30 3.81 2.97 --- --- CB141 Cg4, 123-174 Strong 7.76 8.39 7.89 7.60 7.84 7.36 7.56 7.57 7.35 7.32 7.09 6.96 6.81 6.82 6.96 7.12 6.05 CB142 A, 0-3 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB142 Cg1, 3-36 Strong 8.13 8.50 7.97 7.43 7.46 7.22 6.10 6.48 6.38 5.44 4.36 3.12 2.79 --- --- --- --- CB142 Cg2, 36-100 Strong 7.64 8.21 7.85 7.43 7.00 6.43 5.41 5.10 4.34 3.63 3.25 3.03 2.83 --- --- --- --- CB142 Oab, 100-131 Strong --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB142 Ab, 131-134 Strong 7.46 7.91 7.30 6.41 5.27 4.31 3.94 3.70 3.51 3.21 2.40 2.32 2.20 --- --- --- --- CB142 BAgb, 134-142 Strong 7.67 8.29 7.69 6.27 4.27 3.64 3.83 3.12 3.12 2.91 2.57 2.21 2.12 --- --- --- --- CB142 Cgb, 142-149 Strong 7.65 7.85 7.40 6.20 3.96 3.61 3.50 3.41 3.06 2.83 2.54 2.29 2.18 --- --- --- --- CB143 A, 0-3 None --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- --- CB143 Cg1, 3-61 Strong 7.78 7.94 7.50 6.68 5.97 5.60 5.58 5.55 4.67 4.12 3.24 2.88 2.88 --- --- --- --- CB143 Cg2, 61-95 Strong 7.82 8.11 7.39 6.39 4.53 3.95 3.62 3.45 3.33 3.02 2.31 2.23 2.45 --- --- --- --- CB143 Cg3, 95-108 Weak 7.58 8.10 7.33 6.05 3.79 3.36 3.26 3.15 2.89 2.72 2.24 2.19 2.16 --- --- --- --- CB143 2Cg4, 108-137 None 6.51 7.31 7.31 6.54 6.36 6.37 6.89 7.64 7.49 7.52 7.47 7.82 7.70 7.81 7.90 7.77 7.71 492 Appendix F: Salinity Data 493 Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB01 A, 0-14 cm 269 2.38 1523 19.2 6.2 CB01 Cg1, 14-76 cm 228 3.28 2099 27.0 9.1 CB01 Cg2, 76-103 cm 311 3.84 2458 30.9 10.4 CB01 Cg3, 103-170 cm 285 4.04 2586 34.0 10.7 CB01 Cg4, 170-210 cm 482 4.72 3021 30.1 18.6 CB04 Cg1, 6-32 cm 662 5.39 3450 33.5 22.2 CB04 Cg2, 32-111 cm 438 2.55 1632 19.0 8.3 CB04 Cg3, 111-149 cm 579 1.71 1094 9.8 5.6 CB09 A2, 2-16 cm 323 4.55 2912 35.0 11.3 CB09 Cg1, 16-22 cm 232 3.60 2304 35.8 8.3 CB09 Cg2, 22-42 cm 142 2.26 1446 28.5 4.0 CB09 Cg/Bwb 42-53 cm 166 1.85 1184 19.9 3.3 CB09 2Bgb, 53-76 cm 196 1.19 762 11.7 2.3 CB09 2Bwb1, 76-98 cm 134 0.97 623 14.4 1.9 CB09 2Bwb2, 98-108 cm 249 0.54 344 6.3 0.9 CB09 2BCgb, 108-118 cm 120 0.55 353 8.9 1.1 CB09 2Cgb1, 118-133 cm 141 0.31 195 4.1 0.6 CB09 2Cgb2, 133-151 cm 126 0.11 67 1.9 0.2 CB10 A, 0-17 cm 313 2.92 1869 25.5 8.0 CB10 Cg1, 17-51 cm 228 2.23 1427 26.2 6.0 CB10 2Cg2, 51-64 cm 370 4.43 2835 35.7 13.2 CB10 2Cg3, 64-84 cm 373 4.58 2931 32.0 11.9 CB10 3Cg4, 84-89 cm 276 4.13 2643 38.4 10.4 CB10 3Cg5, 89-134 cm 245 3.53 2259 38.3 9.4 CB11 A2, 2-12 cm 406 4.00 2559 28.1 11.4 CB11 Cg1, 12-36 cm 635 4.30 2752 24.7 15.7 CB11 Cg2, 36-56 cm 1361 6.85 4384 32.2 43.8 CB11 Oab1, 56-83 cm 3163 5.40 3456 22.3 70.5 CB11 Oab2, 83-109 cm 3991 4.14 2650 18.7 74.6 CB11 2Ab, 109-115 cm 1003 3.20 2048 16.1 16.1 CB11 2Cgb, 115-122 cm 288 2.33 1491 19.0 5.5 494 Appendix F: Continued. Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB16 A2, 2-22 cm 243 3.14 2010 31.4 8.9 CB16 Cg1, 22-37 cm 291 3.26 2086 28.9 8.6 CB16 Cg2, 37-67 cm 259 3.28 2099 29.5 7.6 CB16 Cg3, 67-80 cm 227 3.44 2201 31.4 8.3 CB16 Cg4, 80-114 cm 258 3.38 2163 34.2 8.8 CB16 Cg5, 114-187 cm 188 3.40 2176 31.4 7.8 CB16 Cg6, 187-215 cm 258 3.25 2080 33.2 8.4 CB17 A, 0-8 cm 269 3.75 2400 32.7 8.8 CB17 Cg/A 8-32 cm 264 3.47 2221 29.4 7.8 CB17 Cg1, 32-54 cm 449 4.45 2848 33.0 14.8 CB17 Cg2, 54-77 cm 428 4.32 2765 30.5 13.0 CB17 2Cg3, 77-102 cm 205 3.91 2502 47.7 9.8 CB17 2Cg4, 102-148 cm 205 2.99 1914 36.2 7.4 CB18 Cg, 8-50 cm 757 5.35 3424 29.5 22.3 CB18 Cg, 50-100 cm 581 5.35 3424 33.3 19.3 CB18 Cg, 100-150 cm 714 6.42 4109 45.4 32.4 CB18 Cg, 150-200 cm 538 5.61 3590 36.9 19.8 CB18 Cg, 200-250 cm 590 5.45 3488 32.4 19.1 CB21 A1, 0-2 cm ND 30.8 CB21 A2, 2-18 cm 815 6.42 4109 37.7 9.3 CB21 Ab, 58-62 cm 697 2.04 1306 13.3 4.0 CB21 BAgb, 62-71 cm 341 1.59 1018 11.7 2.1 CB21 Btg, 71-96 cm 284 0.89 568 7.5 0.3 CB21 2Cgb, 96-134 cm 195 0.12 76 1.4 CB26 A 0-2 cm 237 4.19 2682 37.0 8.8 CB26 Cg, 2-28 cm 226 5.81 3718 54.7 12.4 CB26 A', 28-50 cm 2203 7.23 4627 32.0 70.6 CB26 C'g, 50-70 cm 1603 4.98 3187 20.4 32.6 CB26 Cg/Oa, 71-103 cm 2394 5.50 3520 22.1 53.0 CB26 Oab, 103-132 cm 2494 3.05 1952 10.1 25.2 CB26 Ab, 132-137 cm 1214 2.01 1286 11.1 13.5 CB26 Btgb, 137-150 cm 229 1.57 1005 15.2 3.5 495 Appendix F: Continued. Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB39 A2, 1-12 cm 751 3.75 2400 23.8 15.8 CB39 Cg1, 12-43 cm 629 4.11 2630 21.0 15.4 CB39 Cg2, 43-57 cm 943 3.18 2035 14.7 15.5 CB39 Cg3, 57-126 cm 649 1.07 685 6.4 3.5 CB39 2Cg4, 126-161 cm 253 0.50 323 4.4 1.1 CB39, 2Cg5, 161-198 cm 182 0.20 128 2.0 0.4 CB45 A, 0-6 cm 251 2.93 1875 45.6 11.9 CB45 Cg/A, 6-33 cm 240 3.67 2349 50.0 8.8 CB45 Cg1, 33-88 cm 252 3.96 2534 40.7 10.9 CB45 Cg2, 88-99 cm 301 5.94 3802 78.6 26.6 CB45 2Cg3, 99-142 cm 566 6.06 3878 34.5 25.8 CB45 2Cg4, 142-186 cm 607 5.81 3718 33.5 33.2 CB50 A2, 3-21 cm 448 4.69 3002 36.7 16.2 CB50 Cg/A, 21-45 cm 365 5.30 3392 46.8 17.1 CB50 Cg1, 45-60 cm 391 4.80 3072 36.0 14.0 CB50 Cg2, 60-92 cm 324 4.06 2598 34.3 11.1 CB50 Cg3, 92-160 cm 317 4.30 2752 35.7 11.3 CB52 A1/A2, 0-10 cm 434 4.95 3168 40.0 15.8 CB52 Cg1, 10-21 cm 417 4.72 3021 34.3 14.2 CB52 2Cg2, 21-39 cm 579 6.54 4186 39.5 33.5 CB52 2Cg3, 39-59 cm 598 5.26 3366 30.2 28.5 CB52 2Cg4, 59-86 cm 863 6.13 3923 32.2 32.4 CB52 2Cg5, 86-115 cm 621 6.03 3859 39.3 18.2 CB52 2Cg6, 115-138 cm 631 5.54 3546 34.5 14.5 CB55 A2, 3-12 cm 273 2.12 1357 21.7 5.9 CB55 Cg1, 12-41 cm 390 3.53 2259 26.4 10.3 CB55 Cg2, 41-90 cm 316 3.40 2176 31.0 9.8 CB55 2Cg3, 90-143 cm 413 3.01 1926 22.4 9.2 CB55 2Cg4, 143-162 cm 307 3.21 2054 27.0 8.3 CB55 2Cg5, 162-198 cm 361 3.73 2387 28.9 10.5 496 Appendix F: Continued. Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB56 A2, 2-10 cm 387 4.52 2893 33.3 12.9 CB56 Cg1, 10-31 cm 288 3.33 2131 29.0 8.4 CB56 Cg2, 31-49 cm 273 4.66 2982 39.0 10.6 CB56 Cg3, 49-72 cm 304 3.74 2394 31.9 9.7 CB56 Cg4, 72-90 cm 284 2.81 1798 25.6 7.3 CB56 Cg5, 90-122 cm 263 3.53 2259 36.3 9.4 CB56 Cg6, 122-137 cm 361 3.78 2419 26.0 9.4 CB56 2Ab, 137-156 cm 601 3.69 2362 23.2 14.0 CB58 A2, 3-14 cm 310 3.36 2150 25.8 8.0 CB58 Cg1, 14-37 cm 311 2.45 1568 18.0 5.6 CB58 Cg2, 37-106 cm 622 4.91 3142 34.2 21.3 CB58 2Cg3, 106-162 cm 382 3.41 2182 26.2 10.0 CB74 A2, 2-19 cm 523 3.53 2259 25.9 13.5 CB74 Cg1, 19-55 cm 335 2.20 1408 22.1 6.5 CB74 Cg2, 55-89 cm 282 2.92 1869 27.4 7.9 CB74 Cg3, 89-109 cm 358 4.13 2643 29.4 13.4 CB74 2Cg4, 109-142 cm 204 3.06 1958 27.8 7.1 CB74 2Cg5, 142-174 cm 237 1.71 1094 16.8 3.9 CB79 A2, 3-10 cm 276 4.80 3072 38.6 10.7 CB79 Cg1, 10-50 cm 313 3.68 2355 30.7 9.6 CB79 Cg2, 50-86 cm 261 3.54 2266 30.7 8.0 CB79 Cg3, 86-123 cm 236 2.96 1894 29.3 6.9 CB91 Cg1, 3-54 cm 430 3.91 2502 20.1 12.6 CB91 Cg2, 54-61 cm 780 4.32 2765 29.0 15.0 CB91 Cg3, 61-139 cm 804 3.76 2406 19.2 15.6 CB91 Cg4, 139-169 cm 649 3.48 2227 20.5 13.7 CB91 Cg5, 169-191 cm 446 3.10 1984 20.1 7.6 CB94 A2, 1-12 cm 276 4.30 2752 37.8 10.4 CB94 Cg1, 12-33 cm 1119 7.56 4838 36.4 40.7 CB94 2Cg2, 33-94 cm 778 4.74 3034 27.2 22.3 CB94 2Cg3, 94-107 cm 926 4.50 2880 20.7 19.2 CB94 2Cg4, 107-145 cm 994 5.35 3424 29.9 29.7 497 Appendix F: Continued. Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB97 Cg1, 2-76 cm 557 4.39 2810 32.7 22.8 CB97 Cg2, 76-95 cm 470 4.04 2586 26.0 12.4 CB97 Cg3, 95-131 cm 628 3.94 2522 18.8 15.3 CB97 Cg4, 131-145 cm 727 4.28 2739 24.3 20.5 CB97 Cg5, 145-168 cm 800 4.23 2707 19.5 23.7 CB97 Cg/Oa, 168-195 cm 1078 4.78 3059 24.2 32.5 CB 97 Oab1, 195-213 cm 2351 4.18 2675 20.9 51.8 CB97 Oab2, 213-224 cm ND CB97 Ab, 224-245 cm 280 1.09 698 7.2 3.4 CB97 Cgb1, 245-260 cm 253 0.71 451 6.4 1.5 CB97 Cgb2, 260-266 cm ND CB124 A, 0-6 cm 267 2.64 1690 26.3 7.0 CB124 Cg1, 6-48 cm 274 2.58 1651 24.1 6.6 CB124 2Cg2, 48-70 cm 1124 4.54 2906 28.5 32.0 CB124 2Oab1, 70-116 cm 3397 4.97 3181 24.5 83.1 CB124 2Oab2, 116-130 cm 2497 5.61 3590 28.4 70.8 CB124 2Ab, 130-136 cm 451 3.78 2419 25.8 11.6 CB124 2Cgb, 136-157 cm 362 3.57 2285 28.8 10.4 CB130 A2, 4-21 cm 626 5.01 3206 27.9 19.0 CB130 Cg1, 21-58 cm 475 5.13 3283 25.6 16.4 CB130 Cg2, 58-125 cm 509 4.86 3110 28.1 17.6 CB130 Cg2, 125-199 cm 548 5.85 3744 38.2 19.8 CB130 Cg3, 199-275 cm 377 4.68 2995 27.8 15.4 CB130 Cg3, 275-340 cm 546 3.88 2483 17.4 12.4 CB136 A2, 2-18 cm 222 3.77 2413 33.4 9.4 CB136 Cg1, 18-37 cm 459 4.52 2893 29.4 16.1 CB136 2Cg2, 37-93 cm 669 4.45 2848 27.0 15.4 CB136 2Cg3, 93-146 cm 640 4.20 2688 22.8 15.1 CB136 2Cg4, 146-161 cm 651 4.27 2733 23.5 24.8 CB136 2Oab1, 161-187 cm ND CB136 2Oab2, 187-205 cm ND CB136 3Ab, 205-211 cm 562 2.77 1773 29.1 16.0 498 Appendix F: Continued. Sample Moisture content g kg -1 Salinity 1:5 by volume dS m -1 mg L -1 ppt in original soil solution mg g -1 dry soil CB141 A2, 4-13 cm 415 4.25 2720 31.2 12.9 CB141 Cg1, 13-23 cm 341 4.75 3040 20.2 7.9 CB141 Cg2, 23-46 cm 796 5.22 3341 32.6 24.3 CB141 Cg3, 46-123 cm 971 5.20 3328 24.8 21.0 CB141 Cg4, 123-174 cm 787 5.51 3526 28.0 22.5 CB142 Cg1, 3-36 cm 553 3.37 2157 18.8 10.3 CB142 Cg2, 36-100 cm 744 3.20 2048 18.5 12.6 CB142 Oab, 100-131 cm ND CB142 Ab, 131-134 cm 942 1.45 928 6.5 14.9 CB142 BAgb, 134-142 cm 548 0.70 445 3.4 3.5 CB142 Cgb, 142-149 cm 308 0.63 405 5.6 1.4 CB143 Cg1, 3-61 cm 638 2.92 1869 16.2 11.4 CB143 Cg2, 61-95 cm 495 1.27 813 6.6 4.0 CB143 Cg3, 95-108 cm 590 0.78 498 4.5 2.1 CB143 2Cg4, 108-137 cm 450 0.26 168 1.9 0.6 499 Appendix G: Moisture Content and Bulk Density Data 500 Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB01 A, 0-14 cm 322 * 1.34 CB01 Cg1, 14-76 cm 255 * 1.25 CB01 Cg2, 76-103 cm 336 * 1.29 CB01 Cg3, 103-170 cm 315 * 1.30 CB01 Cg4, 170-210 cm 619 * 0.90 CB04 A, 0-6 cm 546 0.98 CB04 Cg1, 6-32 cm 662 0.86 CB04 Cg2, 32-111 cm 438 1.07 CB04 Cg3, 111-149 cm 579 1.09 CB06 A, 0-3 cm 633 0.43 CB06 Cg1, 3-59 cm 772 0.50 CB06 2Cg2, 59-81 cm 342 0.96 CB06 2Cg3, 81-107 cm 210 1.02 CB09 A1, 0-2 cm CB09 A2, 2-16 cm 323 1.40 CB09 Cg1, 16-22 cm 232 1.48 CB09 Cg2, 22-42 cm 142 1.88 CB09 Cg/Bgb, 42-53 cm 166 1.91 CB09 2Bgb, 53-76 cm 196 1.78 CB09 2Bwb1, 76-98 cm 134 1.68 CB09 2Bwb2, 98-108 cm 249 1.92 CB09 2BCgb, 108-118 cm 120 1.73 CB09 2Cgb1, 118-133 cm 141 1.77 CB09 2Cgb2, 133-151 cm 126 1.47 CB10 A, 0-17 cm 313 1.26 CB10 Cg1, 17-51 cm 228 1.26 CB10 Cg2, 51- 64 cm 370 1.16 CB10 2Cg3, 64-84 cm 373 1.35 CB10 3Cg4, 84-89 cm 272 1.36 CB10 3Cg5, 89-134 cm 245 1.27 CB11 A1, 0-2 cm CB11 A2, 2-12 cm 406 1.23 CB11 Cg1, 12-36 cm 635 0.98 CB11 Cg2, 36-56 cm 1361 0.58 CB11 Oab1, 56-83 cm 3163 0.29 CB11 Oab2, 83-109 cm 3991 0.21 CB11 2Ab, 109-115 cm 1003 0.73 CB11 2Cgb, 115-122 cm 288 1.47 * These moisture contents were remeasured for bulk density calculations and differ from those used in salinity measurements. 501 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB16 A1, 0-2 cm 242 * 1.28 CB16 A2, 2-22 cm 282 * 1.21 CB16 Cg1, 22-37 cm 297 * 1.31 CB16 Cg2, 37-67 cm 259 * 1.48 CB16 Cg3, 67- 80 cm 265 * 1.42 CB16 Cg4, 80-114 cm 259 * 1.30 CB16 Cg5, 114-187 cm 249 * 1.49 CB16 Cg6, 187-215 cm 253 * 1.32 CB17 A, 0-8 cm 269 1.47 CB17 Cg/A, 8-32 cm 264 1.54 CB17 Cg1, 32-54 cm 449 1.05 CB17 Cg2, 54-77 cm 428 1.16 CB17 2Cg3, 77-102 cm 205 1.35 CB17 2Cg4, 102-148 cm 205 1.36 CB18 A, 0-8 cm CB18 Cg, 8-50 cm 757 0.87 CB18 Cg, 50-100 cm 581 0.98 CB18 Cg, 100-150 cm 714 0.70 CB18 Cg, 150-200 cm 538 1.00 CB18 Cg, 200-250 cm 590 1.02 CB20 A, 0-8 cm 671 0.64 CB20 Cg1, 8-32 cm 411 1.88 CB20 Cg2, 32-60 cm 377 1.36 CB20 Cg3, 60-115 cm 313 0.89 CB21 A1, 0-2 cm CB21 A2, 2-18 cm 815 0.75 CB21 Oab, 18-58 cm CB21 Ab, 58-62 cm 697 0.78 CB21 BAgb, 62-71 cm 341 1.40 CB21 Btgb, 71-96 cm 284 1.45 CB21 Cgb, 96-134 cm 195 1.41 * These moisture contents were remeasured for bulk density calculations and differ from those used in salinity measurements. 502 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB26 A, 0-2 cm 237 1.65 CB26 Cg, 2-28 cm 226 1.61 CB26 A?, 28-50 cm 2203 0.38 CB26 C?g, 50-70 cm 1603 0.58 CB26 Cg/Oab, 70-103 cm 2395 0.39 CB26 Oab, 103-132 cm 2494 0.48 CB26 Ab, 132-137 cm 1214 0.54 CB26 Btgb, 137-150 cm 229 1.54 CB31 A2, 4-22 cm 592 074 CB31 Cg1, 22-62 cm 601 0.49 CB31 Cg2, 62-112 cm 592 0.32 CB39 A1, 0-1 cm CB39 A2, 1-12 cm 751 0.48 CB39 Cg1, 12-43 cm 629 0.85 CB39 Cg2, 43-57 cm 943 0.53 CB39 Cg3, 57-126 cm 649 0.32 CB39 2Cg4, 126-161 cm 253 0.84 CB39 2Cg5, 161-198 cm 182 1.44 CB41 A2, 3-17 cm 429 1.31 CB41 Cg1, 17-52 cm 434 1.15 CB41 Cg2, 52-143 cm 542 0.38 CB45 A, 0-6 cm 261 * 1.35 CB45 Cg/A, 6-33 cm 176 * 1.40 CB45 Cg1, 33-88 cm 268 * 1.24 CB45 Cg2, 88-99 cm 339 * 1.23 CB45 2Cg3, 99-142 cm 750 * 0.84 CB45 2Cg4, 142-186 cm 991 * 0.63 CB50 A1, 0-3 cm CB50 A2, 3-21 cm 442 1.01 CB50 Cg/A, 21-45 cm 365 1.07 CB50 Cg1, 45-60 cm 391 1.19 CB50 Cg2, 60-92 cm 324 1.26 CB50 Cg3, 92-160 cm 317 1.32 * These moisture contents were remeasured for bulk density calculations and differ from those used in salinity measurements. 503 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB52 A1 & A2 0-10 cm 434 0.55 CB52 Cg1, 10-21 cm 417 0.82 CB52 2Cg2, 21-39 cm 579 0.72 CB52 2Cg3, 39-59 cm 598 0.73 CB52 2Cg4, 59-86 cm 863 0.60 CB52 2Cg5, 86-115 cm 621 0.80 CB52 2Cg6, 115-138 cm 631 0.84 CB55 A1, 0-3 cm CB55 A2, 3-12 cm 273 1.22 CB55 Cg1, 12-41 cm 390 1.20 CB55 Cg2, 41-90 cm 316 1.19 CB55 2Cg3, 90-143 cm 413 1.14 CB55 2Cg4, 143-162 cm 307 1.34 CB55 2Cg5, 162-198 cm 361 1.24 CB56 A1, 0-2 cm CB56 A2, 2-10 cm 387 1.23 CB56 Cg1, 10-31 cm 288 1.37 CB56 Cg2, 31-49 cm 273 1.52 CB56 Cg3, 49-72 cm 304 1.34 CB56 Cg4, 72-90 cm 284 1.33 CB56 Cg5, 90-122 cm 263 1.27 CB56 Cg6, 122-137 cm 361 1.42 CB56 2Ab, 137-154 cm 546 * 0.91 CB58 A1, 0-3 cm CB58 A2, 3-14 cm 310 1.47 CB58 Cg1, 14-37 cm 311 1.53 CB58 Cg2, 37-106 cm 622 0.81 CB58 2Cg3, 106-162 cm 382 1.19 CB59 A1, 0-5 cm 954 0.27 CB59 A2, 5-24 cm 982 0.51 CB59 Cg1, 24-35 cm 1765 0.33 CB59 Cg2, 35-74 cm 1691 0.41 CB59 Cg3, 74-86 cm 1046 0.49 CB59 Cg4, 86-127 cm 966 0.57 * These moisture contents were remeasured for bulk density calculations and differ from those used in salinity measurements. 504 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB67 A1, 0-2 cm CB67 A2, 2-13 cm 429 0.89 CB67 Cg/A, 13-35 cm 582 1.59 CB67 2Cg1, 35-73 cm 747 0.90 CB67 2Cg2, 73-135 cm 747 0.76 CB67 2Cg3, 135- cm 482 0.89 CB70 A1, 0-5 cm CB70 A2, 5-19 cm 487 0.71 CB70 2Cg1, 19-44 cm 521 0.73 CB70 2Cg2, 44-78 cm 686 0.81 CB70 2Cg3, 78-92 cm 758 0.72 CB70 2Cg4, 92-127 cm 803 0.68 CB72 A1, 0-2 cm CB72 A2, 2-13 cm 570 1.35 CB72 Cg1, 13-48 cm 495 1.85 CB72 Cg2, 48-69 cm 690 0.68 CB72 Cg3, 69-107 505 0.84 CB74 A1, 0-2 cm CB74 A2, 2-19 cm 522 * 0.91 CB74 Cg1, 19-55 cm 294 * 1.15 CB74 Cg2, 55-89 cm 288 * 1.27 CB74 Cg3, 89-109 cm 455 * 1.08 CB74 2Cg4, 109-142 cm 257 * 1.48 CB74 2Cg5, 142-174 cm 235 * 1.48 CB79 A1, 0-3 cm CB79 A2, 3-10 cm 276 1.56 CB79 Cg1, 10-50 cm 313 1.33 CB79 Cg2, 50-86 cm 261 1.53 CB79 Cg3, 86-123 cm 236 1.46 CB81 A1, 0-2 cm 586 0.92 CB81 A2, 2-18 cm 478 0.29 CB81 Cg1, 18-154 cm 562 0.66 * These moisture contents were remeasured for bulk density calculations and differ from those used in salinity measurements. 505 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB86 A, 0-3 cm CB86 Cg1, 3-35 cm 668 0.86 CB86 Cg2, 35-93 cm 958 0.48 CB86 Cg3, 93-105 cm 700 0.80 CB90 A, 0-2 cm CB90 Cg1, 2-32 cm 629 1.20 CB90 Cg2, 32-42 cm 904 0.79 CB90 Cg3, 42-72 cm 1142 0.54 CB90 Cg4, 72-95 cm 775 1.20 CB90 Cg5, 95-114 cm 788 0.70 CB91 A, 0-3 cm CB91 Cg1, 3-54 cm 430 0.72 CB91 Cg2, 54-61 cm 780 1.24 CB91 Cg3, 61-139 cm 804 0.37 CB91 Cg4, 139-169 cm 649 0.45 CB91 Cg5, 169-191 cm 446 0.65 CB93 A1, 0-4 cm CB93 A2, 4-15 cm 543 1.11 CB93 Cg1, 15-42 cm 548 1.47 CB93 Cg2, 42-81 cm 826 0.67 CB93 Cg3, 81-210 cm 655 0.28 CB94 A1, 0-1 cm CB94 A2, 1-12 cm 276 1.42 CB94 2Cg1, 12-33 cm 1119 0.68 CB94 2Cg2, 33-94 cm 777 0.76 CB94 2Cg3, 94-107 cm 926 0.87 CB94 2Cg4, 107-145 cm 994 0.65 CB97 A, 0-2 cm CB97 Cg1, 2-76 cm 557 0.54 CB97 Cg2, 76-95 cm 470 0.61 CB97 Cg3, 95-131 cm 628 0.67 CB97 Cg4, 131-145 cm 727 0.71 CB97 Cg5, 145-168 cm 800 0.43 CB97 Oab/Cg, 168-195 cm 1078 0.67 CB97 Oab1, 195-213 cm 2351 0.21 CB97 Oab2, 213-224 cm CB97 Ab, 224-245 cm 280 0.66 CB97 Cgb1, 245-260 cm 253 0.91 CB97 Cgb2, 260-266 cm 436 0.69 506 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB100 A, 0-3 cm CB100 Cg1, 3-53 cm 915 0.67 CB100 Cg2, 53-80 cm 521 1.13 CB100 Cg3, 80-100 cm 874 0.81 CB106 A1, 0-3 cm CB106 A2, 3-16 cm 450 1.87 CB106 Cg1, 16-53 cm 492 1.08 CB106 Cg2, 53-69 cm 811 1.61 CB106 Cg3, 69-165 cm 1121 0.10 CB111 A1, 0-3 cm CB111 A2, 3-20 cm 653 0.63 CB111 Cg1, 20-42 cm 592 0.80 CB111 Cg2, 42-200 cm 839 0.26 CB117 A, 0-16 cm 270 1.13 CB117 Cg1,16-34 cm 732 1.12 CB117 Cg2, 34-97 cm 823 0.53 CB117 Cg3, 97-163 cm 534 0.68 CB118 A, 0-9 cm 587 1.15 CB118 Cg1, 9-19 cm 634 0.72 CB118 Cg2, 19-117 cm 677 0.50 CB119 A, 0-17 cm 600 0.72 CB119 Cg1, 17-44 cm 550 0.91 CB119 Cg2, 44-73 cm 536 0.94 CB119 Cg3, 73-99 cm 277 1.34 CB120 A, 0-12 cm 570 0.21 CB120 Cg1, 12-31 cm 432 0.79 CB120 2Cg2, 31-56 cm 474 0.87 CB120 2Cg3, 56-81 cm 192 1.37 CB120 2Cg4, 81-102 cm 260 1.23 CB121 A, 0-12 cm 711 0.61 CB121 Cg1, 12-52 cm 939 0.47 CB121 Cg2, 52-89 cm 848 0.65 CB121 Cg3, 89-197 cm 890 0.46 507 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB124 A, 0-6 cm 267 1.28 CB124 Cg1, 6-48 cm 274 1.34 CB124 2Cg2, 48-70 cm 1124 0.50 CB124 2Oab1, 70-116 cm 3397 0.22 CB124 2Oab2, 116-130 cm 2497 0.29 CB124 3Ab, 130-136 cm 451 1.15 CB124 3Cgb, 136-157 cm 362 1.19 CB127 A, 0-22 cm 726 1.23 CB127 Cg1, 22-51 cm 946 0.54 CB127 Cg2, 51-102 cm 544 0.75 CB130 A1, 0-4 cm CB130 A2, 4-21 cm 626 0.51 CB130 Cg1, 21-58 cm 475 0.93 CB130 Cg2, 58-125 cm 509 1.11 CB130 Cg2, 125-199 cm 548 0.82 CB130 Cg3, 199-275 cm 377 1.02 CB130 Cg3, 275-340 cm 546 0.86 CB136 A1, 0-2 cm CB136 A2, 2-18 cm 222 0.16 CB136 Cg1, 18-37 cm 459 1.41 CB136 2Cg2, 37-93 cm 669 0.66 CB136 2Cg3, 93-146 cm 640 1.06 CB136 2Cg4, 146-161 cm 651 0.49 CB136 2Oab1, 161-187 cm CB136 2Oab2, 187-205 cm CB136 3Ab, 205-211 cm 562 0.66 CB141 A1, 0-4 cm CB141 A2, 4-13 415 0.70 CB141 Cg1, 13-23 cm 341 0.99 CB141 Cg2, 23-46 cm 796 0.88 CB141 Cg3, 46-123 cm 971 0.61 CB141 Cg4, 123-174 cm 787 0.75 CB142 A, 0-3 cm CB142 Cg1, 3-36 cm 553 0.97 CB142 Cg2, 36-100 cm 744 0.54 CB142 Oab, 100-131 cm CB142 Ab, 131-134 cm 942 0.86 CB142 BAgb, 134-142 cm 548 1.56 CB142 Cgb, 142-149 cm 308 2.21 508 Appendix G: Continued. Pedon Sample Moisture Content g kg -1 Bulk Density g cm -3 CB143 A, 0-3 cm CB143 Cg1, 3-61 cm 638 0.66 CB143 Cg2, 61-95 cm 495 0.77 CB143 Cg3, 95-108 cm 590 1.94 CB143 2Cg4, 108-137 cm 450 1.06 CB144 A, 0-29 cm 643 0.68 CB144 Cg1, 29-51 cm 737 0.88 CB144 2Cg2, 51-75 cm 558 0.63 CB144 2Cg3, 75-104 cm 445 0.85 509 Appendix H: Particle-Size Data 510 Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB01 A, 0-14 cm Fine Sand 99.5 0.2 0.3 0.0 6.2 34.4 58.3 0.6 CB01 Cg1, 14-76 cm Fine Sand 99.1 0.5 0.4 0.3 7.3 34.0 56.6 0.8 CB01 Cg2, 76-103 cm Fine Sand 98.0 1.2 0.8 0.0 0.7 3.1 83.9 10.2 CB01 Cg3, 103-170 cm Fine Sand 91.6 4.9 3.6 0.0 0.2 1.4 74.1 15.8 CB01 Cg4, 170-210 cm Loamy Fine Sand 81.0 10.8 8.2 0.1 0.1 0.3 57.3 23.2 CB04 A, 0-6 cm --- --- --- --- --- --- --- --- --- CB04 Cg1, 6-32 cm Silt Loam 18.9 57.6 23.5 0.1 0.2 0.2 1.3 17.0 CB04 Cg2, 32-111 cm Silty Clay Loam 27.7 45.4 27.0 0.1 0.3 1.2 7.6 18.4 CB04 Cg3, 111-149 cm Silty Clay Loam 13.7 53.1 33.2 0.0 0.5 2.0 7.1 4.1 CB06 Cg1, 3-59 cm Silty Clay Loam 12.7 58.0 29.3 0.0 0.3 0.7 3.6 8.0 CB06 2Cg2, 59-81 cm Fine Sandy Loam 64.5 24.5 11.0 0.4 2.5 10.7 43.9 7.0 CB06 2Cg3, 81-107 cm Fine Sandy Loam 69.0 19.1 11.9 0.2 1.5 9.5 49.4 8.3 CB09 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB09 A2, 2-16 cm Loamy Fine Sand 81.0 10.8 8.3 0.6 4.8 14.8 52.8 7.9 CB09 Cg1, 16-22 cm Loamy Fine Sand 84.9 9.2 5.9 1.4 7.2 17.5 53.2 5.7 CB09 Cg2, 22-42 cm Fine Sandy Loam 69.5 23.9 6.6 0.7 3.1 16.1 44.2 5.5 CB09 Cg/Bgb, 42-53 cm Fine Sandy Loam 74.0 19.2 6.8 0.5 3.5 16.7 47.9 5.3 CB09 2Bgb, 53-76 cm Fine Sandy Loam 69.7 19.5 10.8 0.7 3.4 15.7 44.2 5.7 CB09 2Bwb1, 76-98 cm Loamy Fine Sand 84.9 5.5 9.6 0.4 3.7 12.1 60.4 8.2 CB09 2Bwb2, 98-108 cm Sandy Loam 72.7 18.0 9.2 0.9 5.4 17.1 38.9 10.4 CB09 2BCgb, 108-118 cm Loamy Fine Sand 77.5 14.0 8.4 0.1 3.3 15.2 51.1 7.8 CB09 2Cgb1, 118-133 cm Fine Sandy Loam 62.2 30.5 7.3 0.1 1.9 5.0 44.4 10.8 CB09 2Cgb2, 133-151 cm Loamy Fine Sand 86.4 7.4 6.2 0.1 1.5 9.4 69.0 6.5 511 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB10 A, 0-17 cm Fine Sand 97.2 0.9 1.9 0.1 0.8 12.5 79.6 4.2 CB10 Cg1, 17-51 cm Fine Sand 92.3 5.4 2.3 0.0 0.6 2.5 68.4 20.8 CB10 2Cg2, 51- 64 cm Loamy Fine Sand 80.0 13.3 6.7 0.2 0.3 2.1 58.3 19.1 CB10 2Cg3, 64-84 cm Fine Sandy Loam 68.2 21.2 10.6 0.0 0.1 0.8 51.1 16.2 CB10 3Cg4, 84-89 cm Loamy Fine Sand 86.2 10.2 3.5 0.0 0.4 1.7 72.5 11.6 CB10 3Cg5, 89-134 cm Fine Sand 99.6 0.3 0.0 0.1 0.0 0.5 97.1 1.9 CB11 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB11 A2, 2-12 cm Loamy Fine Sand 77.3 13.7 9.0 0.1 0.9 5.6 55.7 15.1 CB11 Cg1, 12-36 cm Silty Clay Loam 11.2 51.3 37.5 0.1 0.4 1.0 6.5 3.2 CB11 Cg2, 36-56 cm Silty Clay Loam 6.5 56.1 37.4 0.2 0.9 0.9 2.8 1.7 CB11 Oab1, 56-83 cm Muck --- --- --- --- --- --- --- --- CB11 Oab2, 83-109 cm Muck --- --- --- --- --- --- --- --- CB11 2Ab, 109-115 cm Clay Loam 28.9 41.7 29.3 0.1 1.7 8.1 14.6 4.3 CB11 2Cgb, 115-122 cm Loam 38.7 44.1 17.2 0.6 4.7 11.7 18.2 3.5 CB16 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB16 A2, 2-22 cm Fine Sand 97.8 0.2 2.0 0.0 0.1 0.7 91.9 5.0 CB16 Cg1, 22-37 cm Fine Sand 95.5 3.0 1.5 0.2 0.6 1.2 79.3 14.2 CB16 Cg2, 37-67 cm Loamy Fine Sand 82.0 10.1 7.9 0.0 0.1 1.0 68.5 12.5 CB16 Cg3, 67- 80 cm Fine Sand 94.0 3.8 2.2 0.1 0.2 1.1 84.7 7.9 CB16 Cg4, 80-114 cm Fine Sand 97.1 1.8 1.1 0.1 0.2 1.0 80.0 15.7 CB16 Cg5, 114-187 cm Fine Sand 88.6 7.8 3.6 0.0 0.2 1.1 70.6 16.7 CB16 Cg6, 187-215 cm Fine Sand 97.9 0.2 1.9 0.1 0.1 0.5 92.7 4.4 512 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB17 A, 0-8 cm Fine Sand 96.5 2.8 0.6 0.1 1.0 17.5 68.7 9.2 CB17 Cg/A, 8-32 cm Fine Sand 96.4 2.7 0.8 0.1 1.2 12.7 73.9 8.5 CB17 Cg1, 32-54 cm Fine Sandy Loam 73.9 17.6 8.5 0.1 0.1 0.8 51.1 21.8 CB17 Cg2, 54-77 cm Loamy Fine Sand 81.5 12.0 6.5 0.0 0.4 4.3 66.2 10.5 CB17 Cg3, 77-102 cm Fine Sand 99.1 0.1 0.7 0.2 1.5 6.1 87.8 3.5 CB17 Cg4, 102-148 cm Fine Sand 99.1 0.0 0.9 0.0 0.2 1.4 89.8 6.7 CB18 A, 0-8 cm --- --- --- --- --- --- --- --- --- CB18 Cg, 8-50 cm Silty Clay Loam 18.9 47.1 34.1 0.0 0.1 0.1 8.2 10.4 CB18 Cg, 50-100 cm Clay Loam 23.3 47.7 29.0 0.0 0.2 0.1 8.9 14.1 CB18 Cg, 100-150 cm Silty Clay Loam 10.7 53.1 36.2 0.0 0.1 0.0 1.3 9.3 CB18 Cg, 150-200 cm Silty Clay Loam 19.7 47.0 33.3 0.0 0.0 0.1 3.8 15.8 CB18 Cg, 200-250 cm Clay Loam 29.5 38.8 31.8 0.0 0.1 0.3 13.2 15.8 CB21 A1, 0-2 cm Clay Loam 24.0 48.0 28.0 0.0 0.3 0.9 3.7 19.1 CB21 A2, 2-18 cm Clay Loam 28.1 44.9 27.0 0.1 0.6 1.5 5.0 20.9 CB21 Oa, 18-58 cm Muck Muck --- --- --- --- --- --- --- CB21 Ab, 58-62 cm Loam 30.4 45.4 24.3 0.2 2.2 6.7 15.5 5.8 CB21 BAgb, 62-71 cm Loam 38.9 44.2 16.9 0.2 2.5 8.9 20.2 7.1 CB21 Btgb, 71-96 cm Clay 27.7 25.5 46.9 0.4 1.1 3.2 15.2 7.7 CB21 2Cgb, 96-134 cm Loamy Fine Sand 88.7 5.4 5.8 0.3 4.2 22.8 54.2 7.3 513 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB26 A, 0-2 cm --- --- --- --- --- --- --- --- --- CB26 Cg, 2-28 cm Fine Sand 95.5 2.0 2.4 2.8 3.8 14.0 72.9 2.0 CB26 A?, 28-50 cm Silty Clay 7.3 46.3 46.4 0.3 1.5 1.2 2.7 1.7 CB26 C?g, 50-70 cm Silty Clay 3.0 53.3 437 0.2 0.5 0.7 0.9 0.8 CB26 Cg/Oab, 70-103 cm --- --- --- --- --- --- --- --- --- CB26 Oab, 103-132 cm Muck --- --- --- --- --- --- --- --- CB26 Ab, 132-137 cm Clay Loam 33.6 28.5 37.9 1.3 0.6 0.7 22.7 8.2 CB26 Btgb, 137-150 cm Clay Loam 43.1 29.6 27.3 1.1 0.9 0.9 30.5 9.8 CB29 Cg3, 24-89 cm Loamy Fine Sand 79.6 13.4 7.1 0.1 0.7 3.2 48.5 27.0 CB29 2Ab, 89-111 cm Fine Sand 93.9 3.5 2.6 2.8 7.0 20.0 55.8 8.3 CB31 Cg1, 22-62 cm Clay Loam 20.2 45.7 34.1 1.2 0.1 0.2 8.7 10.0 CB31 Cg2, 62-112 cm Clay Loam 22.1 42.8 35.0 0.0 0.2 1.0 15.9 5.0 CB39 A1, 0-1 cm --- --- --- --- --- --- --- --- --- CB39 A2, 1-12 cm Silty Clay Loam 6.0 57.3 36.7 0.0 0.1 0.3 1.2 4.4 CB39 Cg1, 12-43 cm Silty Clay Loam 7.9 53.7 38.4 0.0 0.3 0.7 1.8 5.0 CB39 Cg2, 43-57 cm Silty Clay 4.0 53.2 42.8 0.0 0.1 0.3 0.9 2.7 CB39 Cg3, 57-126 cm Silt Loam 20.2 53.3 26.5 0.2 1.5 4.5 10.4 3.6 CB39 2Cg4, 126-161 cm Fine Sandy Loam 73.8 15.8 10.4 0.7 5.9 17.4 44.4 5.4 CB39 2Cg5, 161-198 cm Fine Sandy Loam 75.9 17.5 6.5 0.8 5.8 17.2 44.2 8.0 CB41 A2, 3-17 cm Fine Sandy Loam 69.2 19.7 11.1 0.2 0.1 0.1 57.0 11.8 CB41 Cg1, 17-52 cm Clay Loam 34.8 38.0 27.2 4.3 0.8 0.2 15.2 14.3 CB41 Cg2, 52-143 cm Clay Loam 27.2 42.8 30.0 0.0 0.0 0.0 14.4 12.8 514 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB45 A, 0-6 cm Fine Sand 97.2 1.2 1.7 0.0 0.0 5.2 89.4 2.5 CB45 Cg/A, 6-33 cm Fine Sand 98.6 0.3 1.1 0.0 0.1 3.9 93.1 1.5 CB45 Cg1, 33-88 cm Fine Sand 94.8 2.3 2.9 0.0 0.1 1.7 88.1 4.9 CB45 Cg2, 88-99 cm Loamy Fine Sand 83.2 11.0 5.8 0.0 0.1 0.9 61.7 20.5 CB45 2Cg3, 99-142 cm Loam 28.2 47.1 24.7 0.0 0.1 0.1 7.4 20.6 CB45 2Cg4, 142-186 cm Silty Clay Loam 14.7 46.6 38.7 0.0 0.1 0.1 5.5 9.0 CB49 Cg1, 10-42 cm Loam 30.1 44.9 25.0 0.1 0.0 0.0 4.6 25.4 CB49 Cg2, 42-80 cm Sandy Loam 62.4 23.0 14.6 0.5 0.2 0.1 21.7 39.9 CB49 Ab, 80-105 cm Very fine Sandy Loam 57.5 27.8 14.7 0.0 0.9 0.9 11.0 44.6 CB50 A1, 0-3 cm --- --- --- --- --- --- --- --- --- CB50 A2, 3-21 cm Sandy Loam 61.0 25.5 13.5 11.5 3.2 1.5 16.7 28.1 CB50 Cg/A, 21-45 cm Loam 50.9 32.9 16.2 12.0 2.2 1.1 10.6 25.1 CB50 Cg1, 45-60 cm Loam 42.7 35.5 21.8 0.0 0.0 0.1 5.8 36.7 CB50 Cg2, 60-92 cm Loam 49.7 33.3 17.0 0.1 0.3 0.4 8.8 40.1 CB50 Cg3, 92-160 cm Very Fine Sandy Loam 60.3 25.7 14.0 0.0 0.1 0.1 15.1 45.0 CB52 A1 & A2 0-10 cm Sandy Loam 72.3 18.1 9.6 0.0 0.0 0.1 33.6 38.6 CB52 Cg1, 10-21 cm Loam 52.0 31.6 16.5 0.0 0.1 0.1 18.3 33.4 CB52 2Cg2, 21-39 cm Loam 32.2 43.8 24.0 0.0 0.2 0.1 11.3 20.6 CB52 2Cg3, 39-59 cm Loam 42.4 35.9 21.7 0.0 0.0 0.2 18.1 24.1 CB52 2Cg4, 59-86 cm Clay Loam 28.7 41.9 29.4 0.0 0.1 0.2 10.5 17.9 CB52 2Cg5, 86-115 cm Loam 42.6 35.0 22.4 0.0 0.1 0.1 18.7 23.7 CB52 2Cg6, 115-138 cm Sandy Loam 59.1 25.7 15.2 0.0 0.2 0.2 29.3 29.3 515 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB55 A1, 0-3 cm --- --- --- --- --- --- --- --- --- CB55 A2, 3-12 cm Fine Sand 90.1 6.1 3.8 0.1 0.0 0.1 66.9 23.0 CB55 Cg1, 12-41 cm Loamy Fine Sand 80.9 10.5 8.6 0.1 0.2 0.1 62.0 18.9 CB55 Cg2, 41-90 cm Loamy Fine Sand 80.7 10.9 8.3 0.0 0.1 0.1 53.0 27.5 CB55 2Cg3, 90-143 cm Loam 53.4 29.6 17.0 0.0 0.0 0.2 10.9 42.3 CB55 2Cg4, 143-162 cm Sandy Loam 62.9 23.4 13.8 0.0 0.1 0.2 20.9 41.6 CB55 2Cg5, 162-198 cm Loam 35.6 40.1 24.2 0.0 0.0 0.2 5.4 30.1 CB56 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB56 A2, 2-10 cm Fine Sand 94.6 3.2 2.2 0.0 0.1 0.7 87.1 6.7 CB56 Cg1, 10-31 cm Fine Sand 95.5 2.4 2.1 0.2 0.5 1.6 89.2 4.0 CB56 Cg2, 31-49 cm Fine Sand 97.4 0.7 1.9 0.2 0.3 2.4 91.8 2.7 CB56 Cg3, 49-72 cm Loamy Fine Sand 79.2 13.7 7.1 0.0 0.0 0.3 57.4 21.5 CB56 Cg4, 72-90 cm Fine Sand 88.7 6.4 4.9 0.3 0.5 0.5 70.1 17.4 CB56 Cg5, 90-122 cm Fine Sand 95.4 2.2 2.4 0.0 0.2 0.3 84.2 10.7 CB56 Cg6, 122-137 cm Fine Sand 88.7 6.4 5.0 0.6 0.8 0.3 74.0 13.0 CB56 2Ab, 137-154 cm Loamy Fine Sand 80.7 12.6 6.7 0.0 0.1 0.4 56.2 23.9 CB58 A1, 0-3 cm --- --- --- --- --- --- --- --- --- CB58 A2, 3-14 cm Loamy Fine Sand 81.5 15.5 3.0 0.2 0.1 0.2 52.7 28.3 CB58 Cg1, 14-37 cm Fine Sandy Loam 75.8 14.8 9.4 0.1 0.1 0.2 49.7 25.7 CB58 Cg2, 37-106 cm Fine Sandy Loam 67.8 20.4 11.8 0.0 0.2 0.2 21.3 46.0 CB58 2Cg3, 106-162 cm Silty Clay Loam 19.2 48.5 32.3 0.0 0.0 0.0 1.5 17.7 516 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB74 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB74 A2, 2-19 cm Sandy Loam 67.4 22.5 10.1 0.1 0.1 0.1 36.1 31.0 CB74 Cg1, 19-55 cm Loamy Fine Sand 82.9 11.8 5.3 0.0 0.1 0.3 56.9 25.6 CB74 Cg2, 55-89 cm Loamy Fine Sand 87.9 7.5 4.6 0.0 0.0 0.6 72.0 15.3 CB74 Cg3, 89-109 cm Loamy Fine Sand 77.9 13.4 8.7 0.2 0.8 9.6 55.0 12.2 CB74 2Cg4, 109-142 cm Loamy Fine Sand 85.4 7.9 6.7 0.0 1.2 9.9 68.4 5.9 CB74 2Cg5, 142-174 cm Fine Sand 94.5 2.5 3.0 0.0 1.0 9.8 80.9 2.8 CB79 A1, 0-3 cm --- --- --- --- --- --- --- --- --- CB79 A2, 3-10 cm Fine Sand 94.9 2.8 2.3 2.2 0.6 0.9 73.6 17.7 CB79 Cg1, 10-50 cm Fine Sandy Loam 74.8 15.3 9.9 0.0 0.0 0.2 57.7 16.9 CB79 Cg2, 50-86 cm Loamy Fine Sand 80.4 12.0 7.6 0.0 0.1 2.1 57.6 20.6 CB79 Cg3, 86-123 cm Fine Sand 98.2 0.4 1.4 0.0 0.6 5.2 87.5 4.9 CB85 Cg1, 21-33 cm Clay Loam 23.8 44.4 31.7 1.0 1.9 4.9 12.5 3.6 CB85 Cg2, 33-57 cm Clay Loam 26.2 41.5 32.3 0.5 2.3 5.7 14.3 3.4 CB85 2Cg3, 57-92 cm Sandy Loam 74.7 14.7 10.6 10.1 8.7 10.3 40.5 5.0 CB85 2Cg4, 92-120 cm Loamy Fine Sand 87.6 2.7 9.7 18.6 8.6 6.6 50.0 3.8 CB91 A, 0-3 cm --- --- --- --- --- --- --- --- --- CB91 Cg1, 3-54 cm Loam 34.0 41.1 24.9 0.3 1.8 3.7 17.3 10.9 CB91 Cg2, 54-61 cm Sandy Loam 65.2 20.0 14.8 0.3 1.7 18.6 38.7 5.9 CB91 Cg3, 61-139 cm Silty Clay Loam 16.4 48.5 35.1 0.3 0.4 0.7 2.7 12.2 CB91 Cg4, 139-169 cm Loam 42.4 33.2 24.4 0.7 1.9 4.7 23.0 12.2 CB91 Cg5, 169-191 cm Sandy Loam 65.1 19.8 15.1 1.1 4.8 17.7 34.8 6.6 517 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB93 A1, 0-4 cm --- --- --- --- --- --- --- --- --- CB93 A2, 4-15 cm Silt Loam 24.7 51.6 23.7 0.0 0.1 0.0 4.8 19.9 CB93 Cg1, 15-42 cm Silt Loam 25.9 51.7 22.4 0.3 0.2 0.2 2.6 19.0 CB93 Cg2, 42-81 cm Silty Clay Loam 5.4 56.0 38.5 0.0 0.1 0.0 0.3 5.0 CB93 Cg3, 81-210 cm Silty Clay Loam 9.7 53.9 36.3 0.1 0.1 0.1 0.4 9.0 CB94 A1, 0-1 cm --- --- --- --- --- --- --- --- --- CB94 A2, 1-12 cm Fine Sand 96.0 1.8 2.2 0.6 4.8 30.5 55.9 4.1 CB94 2Cg1, 12-33 cm Silty Clay 8.4 50.0 41.5 0.2 1.0 3.0 3.3 1.0 CB94 2Cg2, 33-94 cm Silty Clay 4.7 53.5 41.8 0.2 0.5 0.4 1.2 2.4 CB94 2Cg3, 94-107 cm Silty Clay 3.7 51.7 44.5 0.4 0.3 0.2 0.5 2.2 CB94 2Cg4, 107-145 cm Silty Clay 4.9 53.3 41.8 0.0 0.5 0.2 1.0 3.2 CB97 A, 0-2 cm --- --- --- --- --- --- --- --- --- CB97 Cg1, 2-76 cm Silt Loam 23.5 52.9 23.6 0.1 0.1 0.2 2.1 21.0 CB97 Cg2, 76-95 cm Loam 31.9 46.1 21.9 0.0 0.2 0.2 13.7 17.8 CB97 Cg3, 95-131 cm Silty Clay Loam 17.2 47.4 35.4 0.0 0.1 0.1 7.2 9.8 CB97 Cg4, 131-145 cm Silty Clay Loam 19.8 45.9 34.3 0.1 0.3 0.4 8.3 10.7 CB97 Cg5, 145-168 cm Silty Clay 12.0 43.9 44.1 0.0 0.1 0.1 4.5 7.3 CB97 Oa/Cg, 168-195 cm --- --- --- --- --- --- --- --- --- CB97 Oab1, 195-213 cm Muck --- --- --- --- --- --- --- --- CB97 Oab2, 213-224 cm Muck --- --- --- --- --- --- --- --- CB97 2Ab, 224-245 cm Loam 43.9 36.0 20.1 0.8 3.6 8.6 16.2 14.7 CB97 2Cgb1, 245-260 cm Loam 53.8 31.6 14.6 1.3 3.7 8.2 22.7 17.9 CB97 2Cgb2, 245-260 cm Sandy Loam 56.8 23.5 19.6 1.2 2.9 3.6 25.9 23.1 518 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB100 Cg1, 3-53 cm Silty Clay Loam 17.7 49.8 32.5 0.0 0.0 0.0 3.4 14.3 CB100 Cg2, 53-80 cm Loam 29.9 44.3 25.8 0.0 0.1 0.3 8.7 20.8 CB100 Cg3, 80-100 cm Silty Clay Loam 16.5 50.3 33.2 1.6 0.0 0.2 2.5 12.3 CB118 Cg2, 19-117 cm Clay Loam 26.1 45.4 28.5 0.0 0.1 0.1 5.6 20.2 CB123 Cg1, 24-47 cm Fine Sand 96.6 2.3 1.0 0.3 0.9 3.8 77.5 14.1 CB123 Cg2, 47-109 cm Loamy Fine Sand 76.2 15.9 7.9 0.0 0.1 0.1 47.3 28.8 CB123 Cg3, 109-148 cm --- --- --- --- --- --- --- --- --- CB123 2Cg4, 148-160 cm Sandy Loam 75.8 17.1 7.1 0.2 0.2 0.9 23.3 51.2 CB124 A, 0-6 cm Fine Sand 98.3 0.1 1.6 0.0 0.1 0.7 89.5 8.0 CB124 Cg1, 6-48 cm Fine Sand 97.7 0.7 1.7 0.0 0.1 1.1 84.6 11.9 CB124 2Cg2, 48-70 cm Silty Clay Loam 15.0 50.1 34.9 0.1 0.4 0.5 7.4 6.7 CB124 2Oab1, 70-116 cm Muck --- --- --- --- --- --- --- --- CB124 2Oab2, 116-130 cm Muck --- --- --- --- --- --- --- --- CB124 3Ab, 130-136 cm Fine Sandy Loam 63.3 26.5 10.2 2.0 4.3 5.7 44.2 7.1 CB124 3Cgb, 136-157 cm Fine Sandy Loam 63.9 27.1 9.0 0.9 4.5 8.2 43.5 6.8 CB127 Cg1, 22-51 cm Silty Clay Loam 15.6 55.1 29.3 0.0 0.2 0.4 1.3 3.7 CB127 Cg2, 51-102 cm Silty Clay Loam 12.6 57.5 29.8 0.1 0.2 0.1 0.8 11.4 CB130 A1, 0-4 cm --- --- --- --- --- --- --- --- --- CB130 A2, 4-21 cm Silty Clay Loam 11.8 54.9 33.3 0.1 0.2 0.3 3.2 7.9 CB130 Cg1, 21-58 cm Clay Loam 22.9 47.3 29.8 0.0 0.1 0.2 2.7 19.9 CB130 Cg2, 58-125 cm Silty Clay Loam 16.6 47.3 36.0 0.0 0.0 0.0 1.7 15.0 CB130 Cg2, 125-199 cm Silty Clay Loam 17.7 48.1 34.3 0.2 0.3 0.5 1.2 15.4 CB130 Cg3, 199-275 cm Clay Loam 27.4 43.3 29.3 0.2 0.2 0.3 2.9 23.7 CB130 Cg3, 275-340 cm Silty Clay Loam 17.6 45.9 36.5 0.1 0.4 1.2 2.6 13.3 519 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB136 A1, 0-2 cm --- --- --- --- --- --- --- --- --- CB136 A2, 2-18 cm Loamy Fine Sand 89.6 5.5 5.0 0.4 4.8 28.4 54.8 1.1 CB136 Cg1, 18-37 cm Loam 35.8 38..0 26.2 0.2 2.3 8.8 21.0 3.4 CB136 2Cg2, 37-93 cm Silty Clay Loam 10.2 59.2 30.6 0.0 0.2 0.5 0.8 8.8 CB136 2Cg3, 93-146 cm Silty Clay Loam 8.0 62.8 29.2 0.1 0.2 0.2 0.5 6.9 CB136 2Cg4, 146-161 cm Silty Clay 5.2 51.6 43.2 0.4 0.6 0.3 1.0 2.9 CB136 2Oab1, 161-187 cm Muck --- --- --- --- --- --- --- --- CB136 2Oab2, 187-205 cm Muck --- --- --- --- --- --- --- --- CB136 3Ab, 205-211 cm Sandy Loam 69.3 22.3 8.4 0.7 3.8 18.4 32.3 14.1 CB141 A1, 0-4 --- --- --- --- --- --- --- --- --- CB141 A2, 4-13 Sandy Loam 76.5 14.9 8.6 10.9 1.2 0.8 24.7 38.9 CB141 Cg1, 13-23 cm Sandy Loam 66.2 21.0 12.8 0.1 4.7 2.8 21.7 37.0 CB141 Cg2, 23-46 cm Clay Loam 23.3 47.7 29.0 0.1 0.6 0.4 3.2 18.9 CB141 Cg3, 46-123 cm Silty Clay Loam 7.8 54.1 38.1 0.0 0.1 0.2 0.9 6.6 CB141 Cg4, 123-174 cm Silty Clay 6.6 52.3 41.1 0.0 0.0 0.0 0.3 6.3 CB142 A, 0-3 cm --- --- --- --- --- --- --- --- --- CB142 Cg1, 3-36 cm Silt Loam 19.1 56.4 24.5 0.0 0.0 0.2 1.0 17.9 CB142 Cg2, 36-100 cm Silty Clay Loam 17.7 51.2 31.1 0.0 0.3 0.3 3.7 13.3 CB142 Oab, 100-131 cm Muck --- --- --- --- --- --- --- --- CB142 Ab, 131-134 cm --- --- --- --- --- --- --- --- --- CB142 BAgb, 134-142 cm Loam 43.5 40.8 15.7 0.0 0.4 1.0 23.8 18.2 CB142 Cgb, 142-149 cm Loam 41.6 42.3 16.1 0.2 0.7 0.6 23.8 16.2 520 Appendix H: Continued. Pedon Sample Texture Class % sand % silt % clay % vcos % cos % ms % fs %vfs CB143 A, 0-3 cm --- --- --- --- --- --- --- --- --- CB143 Cg1, 3-61 cm Loam 27.0 48.3 24.7 0.1 0.2 0.4 2.9 23.3 CB143 Cg2, 61-95 cm Loam 37.3 43.2 19.6 0.1 1.3 4.0 10.3 21.6 CB143 Cg3, 95-108 cm Loam 40.3 42.2 17.5 0.2 2.3 8.4 19.5 10.0 CB143 2Cg4, 108-137 cm Silt Loam 23.5 54.6 21.9 0.1 1.0 4.2 11.8 6.4 521 References Anderson, R.R. 1970. The submerged vegetation of Chincoteague Bay. p. 136?155. In Assateague ecological studies final report: Part1. Environmental information. Nat. Resources Inst. Univ. of Maryland. Contrib. No. 446. Anderson, R.R. 1972. Submersed vascular plants of the Chesapeake Bay and tributaries. Chesapeake Sci. 13:S87-S89. Aston, S.R. 1980. Nutrients, dissolved gases, and general biogeochemistry in estuaries. p. 233-295. In E. Olausson et al. (ed.) Chemistry and biogeochemistry of estuaries. John Wiley, New York. Balduff, D.M., and M.C. Rabenhorst. 2007. 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