ABSTRACT 
 
 
Title of 
Document:  STABILIZATION OF RECYCLED BASE MATERIALS WITH HIGH CARBON FLY ASH  
  
 Bora Cetin, Master of Science, 2009 
  
Directed By: Associate Professor, Ahmet H. Aydilek, Civil and Environmental 
Engineering Department 
 
A study was conducted to stabilize low stiffness road surface material with high carbon 
fly ash. The non-cementitious Maryland fly ash was activated with another recycled 
material, lime kiln dust (LKD). California bearing ratio (CBR) and resilient modulus tests 
were conducted to determine the strength and stiffness, respectively, of the stabilized 
materials.  Addition of LKD and curing of specimens generally increased CBR and 
summary resilient modulus (SMR) and lowered plastic strains, whereas fly ash addition 
alone decreased the strength and stiffness due to the non-cementitious nature of the ash.  
CBR increased with increasing CaO content as well as with CaO/SiO2 and CaO/(SiO2 + 
Al2O3) ratio of the mixtures; however, these parameters could not be correlated with the 
SMR.  The unpaved road materials stabilized with LKD and fly ash is expected to lose 31 
to 67% of their initial moduli after twelve cycles of freezing and thawing. Finally, 
required base thicknesses were calculated using the laboratory-based strength parameters. 
 
 
 
 
 
 
 
 
 
 
STABILIZATION OF RECYLED BASE MATERIALS WITH HIGH CARBON 
FLY ASH   
 
 
 
By 
 
 
Bora Cetin 
 
 
 
 
 
Thesis 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 
Master of Science 
2009 
 
 
 
 
 
 
 
 
 
 
Advisory Committee: 
Associate Professor Dr. Ahmet H. Aydilek, Advisor 
Professor Dr. Sherif M. Aggour, Committee Member 
Professor Dr. Deborah J. Goodings, Committee Member 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
? Copyright by 
Bora Cetin 
2009 
 
 ii 
ACKNOWLEDGEMENT 
First and foremost, I would like to thank my advisor, Professor Ahmet H. 
Aydilek, for his enthusiasm and guidance throughout my graduate studies at the 
University of Maryland ? College Park. Thanks also to Professors Deborah J. Goodings 
and M. Sherif Aggour for being part of my committee. I also would like to thank 
Professor Yucel Guney for his effort in microscopy analysis of cured specimens. Thanks 
to Maryland State Highway Administration to help us to run resilient modulus test and 
provide us necessary information?s about highway construction that are used in State of 
Maryland.  
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 iii 
TABLE OF CONTENTS 
ACKNOWLEDGEMENT ..................................................................................................ii 
TABLE OF CONTENTS...................................................................................................iii 
LIST OF TABLES .............................................................................................................iv 
LIST OF FIGURES.............................................................................................................v 
1. INTRODUCTION.........................................................................................................1 
2. MATERIALS................................................................................................................6 
3. METHODS....................................................................................................................8 
3.1 CALIFORNIA BEARING RATIO TEST..............................................................8 
3.2 RESILIENT MODULUS TEST .............................................................................9 
3.3   MICROSCOPY ANALYSIS????????????????????.11 
4. RESULTS AND ANALYSIS.....................................................................................12 
4.1 RESULTS OF CALIFORNIA BEARING RATIO ..............................................12 
4.2 RESULTS OF RESILIENT MODULUS TEST...................................................15 
5.2.1 Effects of Curing Time, LKD addition on Summary Resilient Moduli and 
Plastic Strain..............................................................................................................15 
5.2.2 Effect of Freeze ? Thaw on Summary Resilient Moduli ................................19 
5. PRACTICAL IMPLICATIONS .................................................................................21 
5.1 HIGHWAY BASE DESIGN ................................................................................21 
5.2 COST CALCULATIONS.....................................................................................23 
6. CONCLUSIONS...........................................................................................................25 
REFERENCES..................................................................................................................27 
TABLES............................................................................................................................33 
FIGURES ..........................................................................................................................42 
APPENDIX A ...................................................................................................................59 
APPENDIX B ...................................................................................................................62 
APPENDIX C ...................................................................................................................70 
APPENDIX D ...................................................................................................................73 
APPENDIX E?????????????????????????????76 
 
 
 
 iv 
LIST OF TABLES 
TABLE 1 a. Index properties of the materials used in the current study. 
TABLE 1 b. Chemical compostion of the fly ashes. Concentrations of major minerals 
determined by X ? ray fluorences spectroscopy analysis. 
TABLE 2.  Legend and compositions of the mixtures. 
TABLE 3.  Power model fitting parameters and measured plastic strains for resilient 
modulus tests. 
TABLE 4.  CBR and summary resilient modulus values. 
TABLE 5.  Chemical compositons of mixtures prepared with three different fly ashes. 
TABLE 6.  Effect of freezing and thawing cycles on summary resilient moduli.. 
TABLE 7.  Required base thickness for different mixture designs for two traffic 
conditions under excellent drainage condition. 
TABLE 8.  Cost analysis for different mixture designs for two different traffic conditions 
under excellent drainage condition. 
 
TABLE A.1. Properties of Maryland fly ashes with ASTM C 618 chemical and 
physical criteria for class C and class F fly ash. 
TABLE B.1. AASHTO 307 ? 99 resilient modulus testing sequence for base and 
subbase materials. 
TABLE C.1. Predicted SMR values based on CBR values. 
TABLE D.1. Base thickness values based on SMR values for traffic case I 
TABLE D.2.  Base thickness values based on SMR values for traffic case II 
TABLE E.1. Required base thickness for different mixture designs for two different 
traffic conditions under good drainage condition.  
TABLE E.2. Required base thickness for different mixture designs for two different 
traffic conditions under fair drainage condition.  
TABLE E.3. Required base thickness for different mixture designs for two different 
traffic conditions under poor drainage condition.  
TABLE E.4.Cost analysis for different mixture designs for two different traffic    
conditions under good drainage condition.  
TABLE E.5.Cost analysis for different mixture designs for two different traffic  
conditions under fair drainage condition. 
TABLE E.6.Cost analysis for different mixture designs for two different traffic  
conditions under poor drainage condition.  
 
 
 v 
LIST OF FIGURES 
FIGURE 1. Comparison of unpaved road material and the two materials used in base 
construction in Maryland to (a) VDOT base materials specification, and (b) 
AASHTO specification. 
FIGURE 2. Effect of curing time on CBR of mixtures prepared with (a) Brandon Shores 
fly ash, (b) Paul Smith fly ash, (c) Dickerson Precipitator fly ash. 
FIGURE 3. SEM photograph of (a) Brandon Shores fly ash, (b) unpaved road material 
amended with 10% Brandon Shores fly ash and 2.5% LKD by weight, (c) 
Dickerson precipitator fly ash, and (d) unpaved road material amended with 
20% Dickerson Precipitator fly ash and 5% LKD by weight. 
FIGURE 4. EDX plot of the SEM photograph of (a) Dickerson Precipitator fly ash, and 
(b) 7-day cured unpaved road material amended with 20% Dickerson 
Precipitator fly ash and 5% LKD by weight. 
FIGURE 5. Effect of LKD contents on (a) CBR and (b) SMR of 28-day cured specimens. 
FIGURE 6. Effect of CaO content, (b) CaO/SiO2, (c) CaO/(SiO2 + Al2O3), and fineness 
on CBR. 
FIGURE 7. Effect of (a) Silica ratio, (b) alumina ratio, (c) lime saturation factor, and (fly 
ash percentage on CBR. 
FIGURE 8. CBR versus measured and predicted SMR for (a) 1 day cured specimens, and 
(b) 7 days cured specimens. 
FIGURE 9. Effect of curing time on SMR of mixtures prepared with (a) Brandon Shores 
fly ash, (b) Paul Smith fly ash, and (c) Dickerson Precipitator fly ash. 
FIGURE 10. Resilient Modulus of the 28-daycured specimens with varying bulk stresses: 
Mixtures prepared with (a) Paul Smith fly ash, and (b) Dickerson Precipitator 
fly ash. 
FIGURE 11. Effect of CaO content, (b) CaO/SiO2, (c) CaO/(SiO2 + Al2O3), and 
fineness on SMR. 
FIGURE 12. Effect of (a) Silica ratio, (b) alumina ratio, (c) lime saturation factor, and (d) 
fly ash percentage on SMR. 
FIGURE 13. Effect of freeze and thaw cycles on SMR values. 
FIGURE 14. Effect of freeze and thaw cycles on water contents. 
FIGURE 15. Summary resilient modulus as a function of base layer thickness. 
FIGURE B.1.Compaction curves for (a) conventional base materials, (b) mixtures 
prepared with Brandon Shores fly ash, (c) mixtures prepared with Paul Smith 
fly ash, and (d) mixtures prepared with Dickerson Precipitator fly ash. 
FIGURE B.2. Photo of Resilient Modulus Testing Equipment. 
FIGURE B.3. GAB (a), URM (b), and BRG (c) . 
 
 vi 
FIGURE C.1. CBR versus measured SMR vs. CBR graph for (a) 1 day cured specimens, 
and (b) 7 days cured specimens. 
FIGURE D.1. Required thickness vs. number of freeze and thaw cycles (a) traffic case I, 
and traffic case II. 
FIGURE E.1.  Effect of LKD addition (a), (b), (c) and traffic conditions (d), (e), (f) on    
total construction fee of the highway base layer. 
 
 1 
1.  INTRODUCTION 
 
American Society of Civil Engineers estimates that $2.2 trillion is needed over a five-
year period to bring the nation?s infrastructure to a good condition.  Establishing a long-
term development and maintenance plan is a national priority.  Large volumes of earthen 
materials are used in construction each year in the United States. In many cases, these 
materials can be replaced with reclaimed highway paving materials, secondary materials, 
suitable waste materials and construction debris that are normally disposed in landfills, 
and can generate millions of dollars savings to taxpayers. Reuse in construction has 
several benefits, including reduction in solid waste disposal costs incurred by industry, 
reduction in landfill requirements, minimization of damage to natural resources caused by 
excavating earthen materials for construction, obtaining added value from waste 
materials, conservation of production energy, and ultimately providing sustainable 
construction and economic growth.  
Legislations have been promulgated in many states that remove barriers to large-
scale beneficial reuse of recycled materials, to reduce construction costs and increase 
sustainability.  As a result, there is a policy shift, both nationally and at the state level, 
aimed at substantially increasing the use of such materials in geotechnical construction. 
For instance, one material that has been increasingly dealt with is road surface material 
from an unpaved road or a road undergoing rehabilitation and uses it as the base layer for 
newly paved roads (Hatipoglu et al. 2008).  Due to its low strength and stiffness, the 
material often has to be stabilized by adding good quality granular material, or by 
blending with hydrated lime and fly ash.  
 
 2 
Over 60% of the electricity generated in the United States is produced by coal 
combustion, with resulting abundant quantities of fly ash as residue, which presents 
another environmental challenge. Fly ash has been used as bulk fill material in 
geotechnical fill, such as in construction of embankments, dikes, and road subgrade 
(DiGioia and Nuzzo 1972, Gray and Lin 1972). The advantages of using fly ash as a bulk 
fill material include low cost, low unit weight, and good strength.  In Eastern parts of the 
United States, anthracite and bituminous coals are burned by the power plants and, as a 
result, non-cementitious ashes (Class F or off-spec fly ashes) are produced.  These fly 
ashes contain high amounts of SiO2 and Al2O3, which can react with an activator rich in 
CaO (e.g., lime, cement, lime or cement kiln dust) in the presence of moisture to form 
cementitious compounds for stabilization applications where additional strength gain is 
needed (e.g., base stabilization). 
Fly ash is generally reused in concrete production.  However, the fly ashes 
produced by several power plants in United States occasionally contains significant 
amounts of unburned carbon (i.e., high loss on ignition) due to the increasingly common 
use of low nitrogen oxide (NOx) and sulphur oxide (SOx) burners in recent years.  This 
ash has a carbon content of 12-25%, cannot be efficiently re-burnt by using current 
technology, and has no value as a concrete additive as the unburned carbon tends to 
adsorb the air entrainment admixtures that are added to the cement to prevent crack 
formation and propagation.  These ashes are typically classified as off-spec fly ashes 
meaning that they do not meet the physical and chemical requirements criteria outlined in 
ASTM C 618.  Recent data indicate that approximately 68% of this high-carbon fly ash 
(HCFA) is placed in landfills, thereby consuming valuable land space and creating the 
 
 3 
potential to impact terrestrial and aquatic resources in Maryland.  Roadways have high 
potential for large volume use of HCFA.  HCFA can be activated with lime kiln dust (a 
disposed residue of lime production plants) and used as the base layer for newly paved 
roads. 
Significant efforts have been made to use fly ashes in stabilization of highways 
base structures, unpaved roads and soil stabilization. Arora and Aydilek (2005) evaluated 
the engineering properties of Class F fly ash amended soils as highway base materials. 
Cement-activated fly ash increased the California bearing ratio (CBR), unconfined 
compression strength, and resilient modulus (Mr) of sandy soils with plastic fines 
contents ranging from 18 to 30%.  Similar observations were made Vishwanathan et al. 
(1997) when silty and sandy soils were stabilized with lime-activated-Class F fly ash for 
their possible use in highway bases. Hatipoglu et al. (2008) showed through unconfined 
compression, CBR and resilient modulus tests that self-cementitious Class C fly ash can 
be a viable binder for stabilization of recycled asphalt pavement material (RPM) for base 
applications.  Li et al. (2007) conducted laboratory tests to evaluate the use of RPM 
blended with fly ash as base course.  CBR of RPM increased from 3-17 to 70-94 with the 
addition of fly ash.  Similarly, addition of fly ash caused more than two-fold increase in 
Mr of laboratory RPM specimens. Camargo (2008) showed that addition of 10-15% by 
weight of Class C fly ash increases the CBR and resilient modulus of recycled pavement 
material (RPM) and road surface gravel by 3 to 6 and 9 to 22 times, respectively.  
Camargo (2008) has also observed a 6 to 11 and 34 to 57 times increase in CBR and 
resilient modulus of road surface gravel when stabilized with 10 and 15% Class C fly ash, 
respectively.  In a study conducted by Wen et al. (2007, 2008) high carbon self-
 
 4 
cementitious fly ash was shown to increase the strength and stiffness of RPM.  CBR and 
Mr of fly ash-stabilized RPM were higher than CBR and Mr for RPM without fly ash; 
both engineering properties were comparable to the CBR of conventional crushed 
aggregate. The plastic deformations for RPM were generally decreased by addition of fly 
ash. 
 Previous research has shown that self-cementing fly ash can be an effective binder 
for stabilizing soils for highway bases (Consoli et al. 2001, Zaman et al. 2003, Arora and 
Aydilek 2005, Edil et al. 2006, Kumar et al. 2007, Buhler and Cerato 2007, Hatipoglu et 
al. 2008, Saylak et al.2008, Shao et al. 2008, Wen et al. 2008, Camargo et al. 2008). 
However, limited information exists on the reuse of high carbon off-spec fly ash in 
construction of highway pavements.  This is particularly important when high carbon fly 
ash is non-cementitious (e.g., Maryland fly ashes) and calcium-rich activators are 
required to generate pozzolanic reactions.  Thus, there is a need to evaluate the strength 
and stiffness of base layers stabilized with high carbon fly ash.  To respond to this need, a 
battery of tests was conducted on unpaved road surface material-fly ash mixtures 
amended with lime kiln dust for its possible use in highway base construction.  California 
bearing ratio (CBR) and resilient modulus (MR) as well as scanning electron microscopy 
(SEM) analyses were conducted to investigate the engineering properties of granular soil-
fly ash mixtures with and without lime kiln dust (LKD), and to study the effect of curing 
time on soil-fly ash-LKD mixtures.  The effect of winter conditions were also evaluated 
by performing resilient modulus tests on the specimens after a series of freeze-thaw 
cycles.   
 
 5 
Another issue that impedes soil stabilization with fly ash is the potential for 
groundwater and other environmental impacts caused by metals in the fly ash.  Fly ash 
contains a small amount of trace metals that can have environmental consequences when 
fly ash is used in geotechnical applications.  Even though an environmental impact 
analysis was necessary, it was left out of the scope of the current project. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 6 
2.  MATERIALS 
 
An unpaved road material (URM) and two conventional base materials were used in this 
study.  The URM was collected from a highway construction site in Caroline County, 
Maryland.  Any debris and foreign materials in the soil were removed by hand and, by 
sieving through the 19 mm sieve. The soil is classified as poorly graded sand with gravel 
(SP) according to Unified Soil Classification System (USCS), and A-1-b (0) according to 
the American Association of State Highway and Transportation Officials (AASHTO) 
Classification System.  The material did not exhibit any plasticity per ASTM D 4318. 
 Two base materials, Bank Run Gravel (BRG) and Graded Aggregate Base 
(GAB), used in highway construction in Maryland were tested as control soils.  GAB 
meets the Maryland State Highway Administration (MDSHA) and AASHTO M-147 
specifications and is termed as a high quality base material in Maryland.  BRG is less 
commonly used in highway construction but was selected due its comparable particle size 
distribution with URM.  GAB was excavated from an underground limestone mine 
located in Frederick, Maryland.  The material was crushed upon mining, passed through a 
series of sieves to meet the gradations given in AASHTO M-147, and stockpiled in pits.  
BRG is originally mined from a sandstone mine located in Middletown, Maryland and 
was stockpiled in pits.  Both materials were collected directly from the pits and delivered 
to the laboratory.  The soils did not contain any organic matter or exhibit plasticity in 
Atterberg limit tests (ASTM D 4318).  The fines content of BRG was 12%, and it was 
classified as SP-SM and A-1-b (0) according to the USCS and AASHTO, respectively.   
GAB included 4% fines by weight and was classified as SP and A-1-a (0) according to 
 
 7 
the USCS and AASHTO, respectively.  The two base materials and URM were stored in 
airtight buckets upon transfer to the laboratory in order to preserve their natural water 
content.  Particle size distribution curves for the unpaved road material and conventional 
base materials are shown in Figure 1 along with the AASHTO M-147 and Virginia 
Department of Transportation (VDOT) specifications used for base construction.  
MDSHA specifications are the same of AASHTO M-147 specifications, thus not 
included in the figure.  The obtained particle size distributions indicated that GAB 
satisfied the AASHTO M-147 and VDOT particle size distribution limits for highway 
bases whereas BRG and URM are tend to be outside of the limits. Physical properties of 
the two soils are summarized in Table 1.  
The fly ashes used in this study were obtained from three power plants in 
Maryland: Brandon Shores, Paul Smith and Dickerson Precipitator.  All three fly ashes 
consisted primarily of silt-size particles and contained 79 to 91% fines (passing the 75-
mm sieve).  Specific gravity (Gs) of fly ashes ranged between 2.17 and 2.37 per ASTM D 
854.  The fly ashes investigated in this study were classified as off-specification fly ashes 
(neither C or F type according to ASTM C 618) due their high loss on ignition (LOI>6).  
The chemical compositions of all three fly ashes are provided in Table 1.  Since the three 
fly ashes do not have high cementing potential (i.e., low CaO), lime kiln dust (LKD) was 
used to initiate pozzolanic reactions for stabilization of the soil. LKD was obtained from 
Carmeuse Lime and Stone Company, Pittsburgh, Pennsylvania, and contained 
approximately 60% CaO by weight.  The specific gravity of LKD is 2.97.  
 
 
 
 8 
3.  METHODS  
 
3.1 California Bearing Ratio Test 
 
The California bearing ratio (CBR) test is a penetration test for evaluation of the 
mechanical strength of road subrgrades and base courses. Soil-fly ash mixtures used in 
the CBR tests were prepared by mixing air-dried soil with a specified percent fly ash by 
weight.  Fly ash percentages were selected as 10 and 20% to cover the typical range used 
in soil stabilization (ACAA 1999, Edil et al. 2002, Bin-Shafique et al. 2004).  Initially, 
high percentages by weight of LKD (10 to 15%) were used as the activator for large 
volume use of this recycled material.  However, due to extremely high strength values 
(CBR>150), more modest percentages of 2.5 and 5% by weight were selected.  All 
specimens for the CBR tests were compacted at their optimum moisture contents (OMC) 
using the standard Proctor effort (ASTM D 698 Method B).  Table 2 provides the OMC 
and maximum dry unit weights (?dm) of the mixtures based on compaction tests.   After 
compaction, the specimens were extruded with a hydraulic jack, sealed in plastic wrap, 
and cured for 1, 7, and 28 days at 100% relative humidity and controlled temperature 
(21? 2 OC) before testing.  CBR tests on specimens without fly ash/LKD were tested 
immediately after compaction (i.e., no curing).  All CBR tests were conducted by 
following the methods outlined in AASHTO T-193 and ASTM D 1883.  The specimens 
were unsoaked and the tests were performed with 1.27 mm/min strain rate using the 
Geotest Instrument S5840 Multi-Loader loading frame.  The equipment had a maximum 
 
 9 
loading capacity of 44.8 kN.  Duplicate specimens were tested for CBR tests as quality 
control, and the averages of these two tests were reported as results. 
 
3.2 Resilient Modulus Test 
   
Resilient modulus test provides the stiffness of a soil under a confining stress and a 
repeated axial load.  The procedures outlined in AASHTO T 307-99, a protocol for 
testing of base and highway base and subbase materials, were followed for resilient 
modulus tests. Unpaved road material and the two conventional base materials were 
mixed with fly ash and LKD at 10-20% and 2.5-5% by weight, respectively, and 
specimens of 101.6 mm in diameter and 230.2 mm in height were compacted in split 
molds at their OMC in eight layers using the standard Proctor energy.  After compaction, 
the specimens were removed from the molds, sealed in plastic wrap, and were cured for 
1, 7, and 28 days at 100% relative humidity and controlled temperature (21? 2 OC) before 
testing.  The testing procedures were the same for BRG and GAB, except the specimens 
were compacted in split molds 152 mm in diameter and 305 mm in height.   
A Geocomp LoadTrac-II loading frame and associated hydraulic power unit 
system was used to load the specimens.  Conditioning stress was 103 kPa.  Confining 
stress was kept between 20.7 and 138 kPa during loading stages, and the deviator stress 
was increased from 20.7 kPa to 276 kPa and applied 100 repetitions at each step.   The 
loading sequence, confining pressure, and data acquisition were controlled by a personal 
computer equipped with RM 5.0 software.  Deformation data were measured with 
 
 10 
external linear variable displacement transducers (LVDTs) that had a measurement range 
of 0 to 50.8 mm.  
Resilient moduli from the last five cycles of each test sequence were averaged to 
obtain resilient modulus for each load sequence.  The resilient modulus of soil is usually 
nonlinear and is dependent on the stress level.  This nonlinear behavior was defined in 
this study using the common model developed by Moosazadh and Witczak (1981): 
 
21RM KK ?=     (1) 
 
where MR is resilient modulus, K1 and K2 are constants, ?  (= d?  + 3? c) is bulk stress, ?c 
is the isotropic confining pressure, and ?d is the deviator stress. A summary resilient 
modulus (SMR) was computed at a bulk stress of 208 kPa, following the guidelines 
provided in NCHRP 1-28A. The approach is also consistent with the suggestions in the 
recent mechanistic-empirical design guide on new and rehabilitated pavement structures 
to provide a constant resilient modulus for chemically stabilized materials (ARA 2004). 
The same bulk stress level was used in this study to verify the model.  The power-model 
based values are summarized in Table 3.  With few exceptions high R2 values (R2 >0.8) 
were obtained from regression analyses performed on the model, indicating that the 
mixtures have a response similar to that of granular materials.   
To observe the effect of winter conditions on resilient moduli, some of the 
mixtures were subjected to strength and hydraulic conductivity tests after a series of 
freeze-thaw cycles.  Specimens with varying fly ash and LKD contents and fly ash types 
 
 11 
were compacted at their optimum moisture contents and 100% of maximum standard 
Proctor dry unit weight and following the procedures outlined in ASTM D 698. After 7 
days of curing, the specimens were frozen in a temperature chamber at -23? 1 OC for 24 
hours and then thawed in a humidity chamber at 100% relative humidity and controlled 
temperature (21? 2 OC) for 23 hours per ASTM D 560.  Specimens were frozen and 
thawed at zero overburden stress. The water content and resilient modulus were measured 
at the end of 4, 8, and 12 freeze-thaw cycles.  Resilient modulus tests were conducted as 
described previously. Duplicate specimens were tested for most of the resilient modulus 
tests as quality control, and the averages of these two tests are reported as results. 
 
3.3 Microscopy Analysis 
 
Scanning electron microscopy (SEM) analyses were conducted on 7-day cured 
specimens. The specimens were initially treated with acetone, and a critical point drying 
apparatus was utilized to replace the acetone with CO2.  The specimens were held on an 
aluminum sample holder with adhesive tape.  Later, they were coated with gold to 
minimize any charge build-up.  Microstructure and chemical composition of the samples 
were examined under LEO 440 Model SEM using the energy dispersive X-ray (EDX) 
technique.   
 
 
 
 
 
 12 
4.  RESULT AND ANALYSIS 
4.1 RESULTS OF CBR TESTS 
 
The CBR test results are provided in Table 4 and Figure 2.  Both BRG and GAB have 
higher CBR than unpaved road material (URM).  The URM has significantly lower CBR 
than 50, a generally accepted limit for base applications (Asphalt Institute 2003), and thus 
required stabilization for use in highway construction.  In all cases, CBR of stabilized 
mixtures is higher than that of URM and is comparable with or higher than the CBR of 
the two conventional base materials even after 1 day of curing.  The data also indicate 
that mixing with only fly ash is not sufficient enough to increase the strength due to its 
non-cementitious nature (i.e., low free lime, CaO) of the ashes, and addition of a lime 
source, such as LKD, is necessary to start pozzolanic reactions. The SEM photographs in 
Figure 3 show the coating of fly ash particles as a result of cement or lime kiln dust 
(LKD) addition, which may be an indicator of an increase in CBR (Conner 1990).  
Relatively higher amounts of calcium are evident as a result of the addition of LKD, as 
shown in the EDX plots of Figure 4.    
  CBR of LKD amended soil-fly ash mixtures also increase with increasing curing 
time (Figure 2).  As LKD is mixed with moist soil, the hydration of calcium oxide (CaO) 
causes the formation of (Ca(OH)2), and disassociation of (Ca(OH)2) favors dissolution of 
silica and alumina in fly ash.  This phenomenon gives rise to formation of calcium 
silicate hydrate (CSH) and calcium aluminate silicate hydrate gels (CASHs) around soil 
particles.  It is speculated that the delayed release of CaO in LKD caused these increases 
and the temperature of the curing chamber and availability of 100% relative humidity 
 
 13 
also contributed to the cementitious reactions.  The increase in CBR after 1 day of curing 
is relatively modest; however, CBR of the 7 and 28-day cured specimens increased up to 
6 and 7 times, respectively.   Similar increases in strength with increasing curing period 
were reported by previous researchers (Vishwanathan et al. 1997, Arora and Aydilek 
2005, Guney et al. 2006). 
Two different amounts of lime kiln dust (LKD) were added to the soil specimens. 
As seen in Figure 5, an increase in LKD amount increases the CBR values significantly 
due to cementation of the particles by the LKD.  The rate of increase is higher initially, 
and increasing the LKD amount from 0% to 2.5% by weight had a greater effect than 
increasing the amount from 2.5% to 5% by weight.  The CBR of unpaved road material 
increases at least three and five times due to addition of 2.5% and 5% LKD by weight, 
respectively.  Similar trends were observed by Consoli et al. (2001) during strength 
testing of soils stabilized with fly ash and carbide lime.  The CBR of all 7-day and 28-day 
cured specimens tested in the current study exceeds 50.  
In order to evaluate the effect of mixture chemical composition on observed 
strength, a paired t-test was conducted at significance level of 0.05, corresponding to 
tcritical =tcr = 2.06 for CBR test results and tcr=2.09 for resilient modulus test results.  CBR 
values are plotted against CaO content, and CaO/SiO2 and CaO/ (SiO2 + Al2O3) ratios 
and fineness of fly ash in Figure 6.  The two ratios stay below 1.0, and are well below 3 
and 2.5, the ratios documented for Portland cement (Table 4).  As expected, the data in 
Figure 6 suggest that CBR increases with increasing CaO content and CaO/SiO2 and 
CaO/(SiO2 + Al2O3) ratios and the best fit curves to the data produced modest R2 values 
(0.79, 0.66 and 0.73, respectively).  Janz and Johansson (2002) indicated that the 
 
 14 
CaO/SiO2 ratio can be a good indicator of pozzolanic reactions, and larger CaO/SiO2 
generally yields higher strength values.  Tastan et al. (2009) showed that the cementing 
potential of materials can be strongly related to CaO content of the binder as well to these 
ratios.  Tastan et al. (2009) also reported that the CaO/SiO2 and CaO/ (SiO2 + Al2O3) 
ratios typically range from 0.5 to 1.0 and from 0.4 to 0.7, respectively, for fly ash-
stabilized subgrade soils. These observations are, in general, consistent with the findings 
obtained in the current study. Fineness of fly ash refers to particles retaining on the 45 
?m sieve (U.S. No. 325 standard sieve size) and defines the surface area of fly ash 
particles present in per unit weight. If the fly ash is self-cementitious (i.e., Class C), 
higher fineness percentages typically enhance the reaction rate which result in faster gain 
of strength at earlier stages.  As seen in Figure 6d, the correlation between the fineness 
and CBR is poor (t < 1.96), mainly due to non-cementitious nature of the Maryland fly 
ashes.   
 Attempts were also made to relate CBR to three commonly used ratios in cement 
production: silica ratio (SR), alumina ratio (AR) and lime saturation factor (LSF).   The 
silica ratio (SR=SiO2/ (Al2O3 + Fe2O3)) represents the required energy to combine raw 
materials in a stabilization application. When SR increases, it becomes harder to combine 
the raw materials whereas a decrease in SR suggests an increase in the ability of solid 
materials to become liquid.  The alumina ratio (Al2O3/Fe2O3) is important as it alumina-
to-iron ratio in cement is known to be an indicator of sulfate resistance, heat generation, 
and admixture compatibility issues. The lime saturation factor (LSF) is dependent on the 
C3S-to-C2S ratio in the finished cement, where the early and delayed age strength 
development is governed by C3S and C2S, respectively (PCA 2009). LSF typically 
 
 15 
remains between 0.95 and 0.98 for Portland cement and higher LSF indicates the 
presence of excess free lime which is likely to remain unreacted in the mixture (Taylor 
1997). No clear trends or correlations can be visualized in Figure 7.  This is not surprising 
as these ratios are generally not used as indicators of pozzolanic reactions.  As mentioned 
before, increase in fly ash content only does not change stresses and no correlation can be 
observed between fly ash percentage and CBR (Figure 7d). 
 
 
4.2 RESULTS OF RESILIENT MODULUS TESTS 
 
4.2.1 Effects of Curing Time, LKD Addition on Summary Resilient Moduli and 
Plastic Strain 
 
Summary resilient moduli of the tested specimens are given in Table 4.  GAB has the 
highest CBR of all three unstabilized materials due to its high gravel content.  The 
measured SMR of GAB falls into the range of suggested SMR for SP or SP-SM soils 
reported in the Mechanistic-Empirical Design Guide (165 to 228 MPa), whereas the same 
is not true for BRG and URM (ARA 2004).   Similar to CBR data, URM has low 
summary resilient modulus, justifying the need for stabilization with a calcium-rich 
binder.  The order of SMR is compatible with that of CBR; however, a strong correlation 
was not obtained when CBR was plotted against SMR (Figure C1 in Appendix).  Camargo 
(2008) also attributed the difference to the application of different magnitudes of 
deformations to the specimens during testing and measurement of two separate 
 
 16 
geomechanical properties (i.e., small deformations and measurement of stiffness during 
resilient modulus test versus large deformations and bearing capacity determination 
during CBR test).   
Attempts were also made in the past to correlate CBR to resilient modulus data by 
using two well-known empirical equations by Powell et al. (1984) and Haukelom and 
Foster (1960), respectively: 
 
                                                            SMR = 7.6CBR0.64           (2) 
 
                                                            SMR = 10CBR           (3) 
 
where SMR is summary resilient modulus in MPa.  As seen in Figure 8, both equations 
overpredict the measured resilient modulus data.  Similar observations were also made by 
Sawangsuriya and Edil (2005) and Acosta et al. (2006).  Due to low correlations observed 
between CBR and SMr (R2=0.33 and 0.32 for 1 and 7-day cured specimens, respectively), 
no further attempt was made to develop an empirical equation to predict resilient 
modulus from the CBR data.  
Average plastic strains were calculated for all base materials during resilient 
modulus testing using data from the LVDTs. Plastic strain for a resilient modulus test 
was calculated as the sum of the plastic strains for each loading sequence, excluding the 
plastic strains in the conditioning phase. The plastic strains (?plastic) for two Maryland 
base materials and URM, along with stabilized soils are summarized in Table 3. BRG and 
GAB showed average plastic strains of 1% and 0.94%, respectively, whereas URM 
 
 17 
showed an average plastic strain of 0.97%. The calculated strains for the high quality 
Maryland base materials are comparable with those of conventional base aggregates 
reported in the literature (Camargo 2008).  The high plastic strain of BRG and URM is 
attributed to their relatively higher sand content (68% and 67%, respectively) as 
compared to GAB (51%), consistent with the observations of Camargo (2008).   
A variation of SMR with curing time is shown in Figure 9.  SMR increases with 
increasing curing time.  The average change in SMR caused during the 1-day curing was 
about 35%, and increasing the curing time from 0 to 1 day had a slightly greater effect 
than increasing the curing time from 1 to 7 or 7 to 28 days (assuming that the SMR of 
mixtures were no different than that of URM at 0 days).  Curing of specimens longer 
periods also resulted in lower plastic strains (Table 3).  Similar to CBR test results, the 
SMR increased with increasing LKD amount due to cementitious reactions formed 
between fly ash and LKD, and the summary resilient modulus of unpaved road material 
increased 1.4 to 4 times as a result of stabilization (Figure 5).  The SMR ranged between 
157 and 510 MPa, and the maximum SMR was recorded for BS20+5 LKD (unpaved road 
material mixed with 20% Brandon Shores fly ash and 5% LKD by weight) upon 28 days 
of curing.  It can be concluded that an LKD content of 5% by weight leads to reasonably 
high SMR values and addition of LKD beyond that amount may not be necessary.  
Moreover, Cross and Young (1997) reported higher initial cracking of recycled pavement 
materials with increasing cementitious fly ash contents.  On the other hand, the maximum 
LKD content was set at 5% in the current study solely considering the cost-effectiveness; 
however, additional testing is required to obtain the LKD contents beyond which SMR no 
longer increases. 
 
 18 
Table 3 summarizes the two constants, K1 and K2, for the resilient modulus power 
function model along with the best fit correlation coefficients. The resilient modulus is 
plotted versus bulk stresses for the mixtures prepared with two of the fly ashes in Figure 
10.  An increase in resilient modulus with increasing bulk stress is observed for all 
specimens, which is in agreement with the behavior generally observed for granular soils 
(AASHTO T-307-99). The optimum moisture content of the mixtures compacted using 
standard Proctor effort range from 9% to 13%, and the difference between the maximum 
dry densities of the specimens is insignificant (Table 2).  Therefore, the difference in 
resilient modulus is attributed solely to the variation in LKD content.  As expected, 
resilient modulus increases with increasing LKD content at a given bulk stress due to 
production of more cementitious compounds with LKD addition. Figure 10 further 
suggests that fly ash generally acts as a bulking agent and does not contribute to resilient 
modulus, as the resilient modulus at a given LKD content and bulk stress either stays the 
same or decreases with increasing fly ash content, with the exception of the specimen 
prepared with 10% Paul Smith fly ash.  LKD addition caused an increase in SMR but also 
decreased the plastic strain of URM.  In general, addition of non-cementitious fly ash did 
not cause significant changes in plastic strains (Table 3). 
  Figure 11 suggests that SMR tends to increase with increasing mixture CaO 
content, and CaO/SiO2 and CaO/(SiO2 + Al2O3) ratios, even though CaO/SiO2 ratio is the 
only one that exhibited correlation with resilient modulus (t>tcritical=2.09).  Furthermore, 
SMR was not correlated with silica ratio, alumina ratio, lime saturation factor, or fly ash 
percentage (Figure 12).   
 
 
 19 
4.2.2 Effect of Freeze-Thaw on Summary Resilient Moduli 
 
Stabilized highway construction material should be able to resist against climatic stresses, 
especially freeze-thaw cycles (TFHRC 2002).  Subjecting the specimens to strength after 
freeze-thaw (F-T) cycles and recording the change in weight have been reported as 
indicators of durability. However, the evaluation of durability by weight loss as a result 
of freeze-thaw cycles (ASTM D 560) has been dropped by some state agencies as the 
procedure is overly severe, and does not totally simulate field conditions.  Previous 
research indicates that 8 to 12 cycles of freezing and thawing could be considered 
adequate in investigating the effect of F-T cycles on different engineering parameters 
including strength (Zaman and Naji 2003). 
In this study, six different mixtures were cured for 7 days as normally practiced in 
pavement construction. The specimens were subjected to resilient modulus tests 
following a series of freezing and thawing cycles.  The test results are summarized in 
Table 6 and Figure 13.  The summary resilient modulus ratio (SMR Ratio = SMRn/ SMRi) is 
the ratio of summary resilient modulus after n freeze-thaw cycles (SMRn) to the initial 
summary resilient modulus (SMRi).   
The specimens either gain strength or lose only 3 to 12% of their initial resilient 
modulus after four cycles, and then SMR starts to decrease indicating the detrimental 
effects of freeze and thaw cycles. The highest decreasing rate of SMR can be observed 
between the fourth and eighth cycle, and the specimens lose 31 to 67% of their initial 
moduli after twelve cycles of freezing and thawing.  Similar trends were observed for 
 
 20 
unbound materials by Simonsen et al. (2002).  Rosa (2006) also reported a 20 to 66% 
reduction in SMR of various coarse and fine-grained soils.    
The effect of freeze-thaw on resilient modulus can be explained in terms of 
retardation or acceleration of the cementitious reactions.  Freezing action retards the 
cementitious reactions, which causes a reduction in stiffness: conversely, thawing action 
contributes to an increase in SMR via accelerating the cementitious reactions.  The 
freezing and thawing compensated each other in first four cycles of soil specimens.  It is 
believed that between cycles of 4 and 12, freezing caused the breaking of the cement 
bonds in the mixture and resulted in a significant decrease in SMR.  As compared to 
previous studies conducted on sandy soils and soils with some plasticity (Arora and 
Aydilek 2005, Rosa 2006, Camargo 2008), a larger change can be observed in the moduli 
of specimens tested in the current study.  This may be attributed to the high gravel 
content and nonplastic nature of the current mixtures, which have relatively high porosity 
and susceptibility to frost action.    
The effect of freeze-thaw is consistent with the volume changes of specimens.  
The volume changes remain nearly constant within the first four cycles, after which 
increases significantly evidenced by the changes in water contents shown in Figure 14.  It 
is believed that freezing process caused breakage of the chemical bonds and allowed 
water to freely penetrate into the pores, thereby causing large increases in water contents, 
i.e., up to 89% increase in water content after 12 cycles of freezing and thawing.   
 
 
 
 
 21 
5.  PRACTICAL IMPLICATIONS 
 
5.1 Highway Base Design 
 
CBR and resilient modulus test results were used to estimate the thickness of the base 
layer in a pavement by following the procedures defined in the AASHTO Guide (1993).  
Low traffic (Case I) and high traffic (Case II) conditions were simulated by using 5 
million and 50 million equivalent single-axle loads (ESALs or W18), respectively.  The 
overall standard deviation (So) and reliability (ZR) were assumed to be 0.35 and 95%, 
respectively.  Structural numbers (SN) for two traffic conditions were back-calculated 
using Equation 2. 
 
 
                                       
 
(4) 
 
where ?PSI is design serviceability loss and MR is the roadbed material effective 
resilient modulus.  The values were selected as 1.9 and 34.5 MPa, respectively, based on 
Huang (1993).  An asphalt layer thickness of 102 mm for Case I and 152 mm for Case II 
was selected.  The resilient modulus of asphalt was assumed to be 2965 MPa, which 
corresponded to a structural coefficient of a1 = 0.44 according to the AASHTO Guide 
(1993).  A resilient modulus of 103 MPa (corresponding to a structural coefficient of a3 = 
( ) ( ) ( ) ( )( ) ( ) 07.8Mlog32.21SN10944.0 5.12.4PSIlog20.01SNlog36.9SZWlog R1019.510100R18 ??+++ ??+?+?+?=
 
 22 
0.11) and a thickness of 406 mm (D3) were assumed for the subbase layer for both cases.  
The structural coefficient of the base layer (a2) was calculated for its corresponding CBR 
or SMR values using the procedure given in the AASHTO Guide (1993).  The CBR and 
SMR of 28-day cured specimens were used due to their common use in highway 
construction.  Finally, the base thicknesses were calculated using the following formula: 
 
m2a
mD3a1D1aSN
2D 2 33
??=      (5) 
 
where m2 and m3 are the drainage modification factors for the base and subbase layer, 
respectively, and were chosen as 1.2, 1.0, 0.8, 0.6 for excellent, good, fair, poor drainage 
conditions, respectively, within the pavement system (Huang 1993).  Table 7 shows the 
required base thicknesses for Cases I and II under excellent drainage conditions. 
Furthermore, the required base thickness decreased with increasing resilient modulus, as 
seen in Figure 15.  The change in drainage conditions require higher base thickneeses as 
reflected in Tables E.1-E.3 in Appendix E.    
The base layer thicknesses of all stabilized mixtures based on SMR are 
consistently lower than that of unpaved road material and generally comparable or lower 
than that of the two typical Maryland base materials.  Increase in fly ash content at fixed 
LKD content results in higher base thicknesses due to non-cementitious nature of the 
ashes used.  In addition, a decrease in amount of lime kiln dust (LKD) and increase in 
traffic load required thicker base layers in highway construction.  An analysis of curing 
time effect on required base thicknesses were not conducted; however, it is well-known 
 
 23 
that increase in curing time is likely to  yield lower base thickness since the specimens 
gain strength at later stages.  As discussed before, winter conditions generally lead to a 
decrease in strength of lime-treated mixes. This would generally require larger base 
thicknesses, in particular after 4 cycles of freezing and thawing as presented in Tables D1 
and D2 and Figure D1 of Appendix. However, it should be noted that the climatic 
stresses may have unexpected effects on the soil mixtures, particularly in short term (i.e., 
during construction), and therefore precautions should be taken to protect specimens from 
in-situ freezing conditions.  
   
5.2 Cost Calculations 
 
A simple cost analysis, considering the material, hauling and transportation costs only, 
was performed to on all soils and mixtures.  In the current study, three different fly ashes 
and one type of lime kiln dust were used at varying percentages by weight.  The road 
construction site was assumed to be the Route 1 expansion project site located in College 
Park, Maryland. The fly ashes were available at no cost. The Brandon Shores, Paul Smith 
and Dickerson power plants were located about 43 km, 101 km, 52 km, respectively, 
from the construction site. The URM, a material commonly used in unpaved road 
construction in Caroline County, Maryland, was available at $4/t.  The distance between 
the construction site and URM plant was 64 km. Lime kiln dust material was available 
from the manufacturer for about $16/t. However the closest lime kiln dust supplier was in 
Pittsburgh, PA which was 390 km away from the construction site. The GAB plant was 
77 km away from the construction site, and the cost of the GAB material was $10/t. The 
 
 24 
BRG plant was 83.2 km away from the construction site and the cost of the BRG 
materials was $10/t. A fuel charge of $0.5/t and hauling costs of $0.25/t were assumed for 
all materials.   
Lane widths in the United States can range from 3 m (low volume roads) to 5 m 
(highway ramps) in width, and a typical design width of 4 m was selected for the Route 1 
expansion project. To represent a typical roadway, a four-lane roadway was considered 
with two 2-m shoulders.  The detailed cost analysis summarized in Table 8 indicates that 
using stabilized URM in a roadway base application has a clear advantage over using 
other conventional earthen base materials.  
The factors that mainly affect the cost are traffic volume and drainage conditions. 
The required base layer thicknesses increase due to a decrease in drainage quality of 
highways (Table E4-E6). Moreover, increasing traffic volume increases the total 
construction cost increases significantly (Figure E1).  Addition of the activator (i.e., 
LKD) decreases the cost, even under low drainage conditions, due to its positive effect on 
required base thickneesses.  
 
 
 
 
 
 
 
 
 
 25 
6. CONCLUSIONS 
 
Roadways are one of the largest construction fields, and reuse of suitable waste materials 
in their construction can provide significant cost savings while meeting the objectives of 
the United States Federal Highway Administration Green Highways Partnerships 
initiative.  A laboratory study was conducted to investigate the feasibility of reusing 
chemically stabilized road surface material in construction of highway bases.  Non-
cementitious off-spec high carbon fly ash was activated lime kiln dust and used to 
stabilize an unpaved road material (URM) collected from Maryland.  The effects of lime 
kiln dust (LKD) and fly ash addition, and curing time on strength and stiffness of 
highway bases were studied.  The effects of winter conditions on stiffness were examined 
by performing resilient modulus tests on the specimens after a series of freeze-thaw 
cycles.  The base thicknesses were calculated for all mixture designs by using their CBR 
and summary resilient moduli (SMR) values.  The observations are summarized as 
follows: 
1) Addition of lime kiln dust (LKD) and curing of specimens increase CBR and SMR 
significantly, whereas increase in fly ash content generally decreases the strength 
and stiffness due to the non-cementitious nature of the high carbon Maryland fly 
ash and that the fact that ash acts as a bulking agent.  Almost all specimens have 
CBR values higher than 50, a limit typically considered for construction of base 
layers.  Measured SMRs were comparable with the ones reported for highway 
bases in previous studies.   
 
 26 
2) Both BRG and GAB exhibited higher CBR and SMR than unpaved road material 
(URM).  The order of SMR was also compatible with that of CBR in spite of the 
differences in nature of the two test methods.  The two Maryland base materials, 
BRG and GAB, had comparable plastic strains with those documented for 
conventional base aggregates in the literature.  In general, lower plastic strains 
were obtained by addition of LKD as well as with increasing curing time whereas 
fly ash addition did not affect the strains significantly.   
3) CBR increased with increasing CaO content as well as with CaO/SiO2 and 
CaO/(SiO2 + Al2O3) ratios; however, these parameters could not be correlated 
with the SMR.  Moreover, silica and alumina ratios and lime saturation factor, 
three common parameters for definition of cementitious activity, are not likely to 
affect the CBR or SMR. 
4) Early stages of freezing and thawing did not cause detrimental effects on resilient 
modulus; however, the unpaved road materials stabilized with LKD and fly ash 
lost 31 to 67% of their initial moduli after twelve cycles of freezing and thawing.  
Such high changes in SMR are attributed to the frost susceptibility of mixtures due 
to their high gravel content and nonplastic nature  
5) Lower base thickness would be required if higher amount of lime kiln dust 
materials is used during construction of the base layer.  It should also be noted 
that an increase in LKD content and decrease in traffic load are likely to decrease 
the required thicknesses.  
 
 27 
6) Significant cost reduction be expected by stabilizing unsuitable roadway materials 
with high carbon fly ash and lime kiln dust while the total cost is mainly affected 
by the traffic volume and pavement drainage conditions 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 28 
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AASHTO Guide (1993). ?Guide for Design of Pavement Structures?, American 
Association of State Highway and Transportation Officials, Washington, D.C. 
ACAA (2003). ?2001 Coal Combustion Product Production and Use?, American Coal 
Ash Association, Denver, Colorado 
ARA (2004). ?Guide for Mechanistic-Empirical Design on New and Rehabilitated 
Pavement Structures,? NCHRP Project 1-37A. Prepared for National Cooperative 
Highway Research Program, Washington, D.C.  
Arora, S. and Aydilek, A.H. (2005). ?Class F Fly Ash Amended Soils as Highway Base 
Materials?, Journal of Materials in Civil Engineering, Vol. 17, No. 6, pp. 640-
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Asphalt Institute (2003). ?Thickness Design ?Highways and Streets?, Manual Series, No. 
1, Asphalt Institute, Lexington, Kentucky, 110 p.  
Bin-Shafique, S., Edil, T., Benson, C., and Senol, A. (2004). ?Incorporating a fly ash 
stabilized layer into pavement design-Case study.? Geotechnical engineering, 
Institution of Civil Engineers, London, Vol. 157, No. GE4, 239?249. 
Buhler, S.R. and Cerato, A.B. (2007). ?Stabilization of Oklahoma Expansive Soils Using 
Lime and Class C Fly Ash?, ASCE Geotechnical Special Publication, 162, pp. 1-
10. 
Camargo, F.F. (2008). ?Strength and Stiffness of Recycled Base Materials Blended with 
Fly Ash?, M.S. Thesis, University of Wisconsin-Madison, 123 p. 
 
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Conner, J.R. (1990). ?Chemical Fixation and Solidification of Hazardous Wastes?, Van 
Nostrand Reinfold, New York, 692 p. 
Consoli, N. C., Prietto P. D. M., Carraro, J. A. H., and Heineck, K., S. (2001). ?Behavior 
of Compacted Soil-Fly Ash-Carbide Lime Mixtures." Journal of Geotechnical 
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Cross, S. A. and Young, D. A. (1997). Evaluation of Type C Fly Ash in Cold-in-Place 
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DiGioia, A. M. and Nuzzo, W. L. (1972). ?Fly Ash as Structural Fill,? J. Power Div., 
ASCE, New York, Vol. 98 (1), pp. 77-92. 
Edil, T.B., Acosta , A.A., and Benson, C.H. (2006). ?Stabilizing Soft Fine-Grained Soils 
with Fly Ash?, Journal of Materials in Civil Engineering, Vol. 18, No. 2, pp. 283-
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Edil, T. B., Benson, C., Bin-Shafique, M., Tanyu, B., Kim, W. and Senol, A. (2002). 
?Field evaluation of construction alternatives for roadways over soft subgrade?, 
Journal of the Transportation Research Board, 1786, pp. 36-48. 
Gray, D. H., and Lin, Y. K. (1972). ?Engineering Properties of Compacted Fly Ash,?J. of 
Soil Mech. and Found. Engrg., ASCE, New York, Vol. 98 (4), pp. 361-380. 
Guney, Y., Aydilek, A.H., and Demirkan, M.M. (2006). ?Geoenvironmental Behavior of 
Foundry Sand Amended Mixtures for Highway Subbases?, Waste Management, 
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Hatipoglu, B., Edil, T., and Benson, C. (2008). ?Evaluation of base prepared from road 
surface gravel stabilized with fly ash?, ASCE Geotechnical Special Publication, 
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Heukelom, W., and Foster, C. (1960). ?Dynamic Testing of Pavements.? Journal of Soil 
Mechanics and Foundation Division, Vol. 86, No. 1, pp.1?28. 
Huang, Y. H. (1993). ?Pavement Analysis and Design?, Prentice-Hall, Inc., New Jersey, 
805 p. 
Janz, M. and Johansson, S.-E. (2002). "The Function of Different Binding Agents in 
Deep Stabilization," Report 9. Swedish Deep Stabilization Research Centre, 
Linkoping, Sweden. 
Kumar, A., Walia, B.S., and Bajaj, A.(2007). ?Influence of Fly Ash, Lime, and Polyster 
Fibers on Compaction and Strength Properties of Expansive Soils?, Journal of 
Materials in Civil Engineering, Vol. 19, No. 3, pp. 242-248. 
Li, L., Benson, C. H., Edil, T. B., Hatipoglu, B., and Tastan, E. (2007). ?Evaluation of 
recycled asphalt pavement material stabilized with fly ash?, ASCE Geotechnical 
Special Publication (CD-ROM), 169.  
Moosazedh, J., and Witczak, M. (1981). ?Prediction of Subgrade Moduli for Soil that 
Exhibits Nonlinear Behavior?, Journal of the Transportation Research Board, 
810, pp. 10-17. 
PCA (2009). Portland Cement Association, www.cement.org 
Powell, W., Potter, J., Mayhew, H., and Nunn, M. (1984). The Structural Design of 
Bituminous Roads, TRRL Laboratory Report 1132, Transportation and Road 
Research Laboratory, Crowthorne, Berkshire, U.K, 62 p. 
Rosa, M. (2006). ?Effect of Freeze and Thaw Cycling on Soils Stabilized using Fly Ash,? 
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Saylak, D., Mishra, S.K., Mejeoumov, G.G.,  and Shon, C.C. (2008). ?Fly Ash-Calcium 
Chloride Stabilization in Road Construction?, Proceedings of 87th Annual Meeting 
(CD ROM), Transportation Research Board, Washington, D.C. 
Sawangsuriya, A. and Edil, T. B. (2005), ?Evaluating stiffness and strength of pavement 
materials, geotechnical engineering.? Geotechnical Engineering, Institution of 
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Shao, L., Liu, S., Du, Y., Jing, F. and Fang, L. (2008). ?Experimental Study on the 
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Simonsen, E., Janoo, V., and Isacsson, U. (2002). ?Resilient properties of unbound road 
material during seasonal frost conditions?, Journal of Cold Region Eng., 16(1), 
pp. 28-50. 
Tastan, O., Benson, C.H., Edil, T.B., and Aydilek, A.H. (2009).  ?Stabilization of Organic 
Soils with Fly Ashes?, Journal of Geotechnical and Geoenvironmental 
Engineering, submitted. 
Taylor, H.F.W. (1997). ?Cement Chemistry?, Second edition, Thomas Telford, Inc.  
Vishwanathan, R., Saylak, D., and Estakhri, C. (1997). ?Stabilization of Subgrade Soils 
Using Fly Ash?, Proceedings of the Ash Utilization Symposium, CAER, Kentucky, 
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Wen, H., Baugh, J., and Edil, T. (2007). ?Use of Cementitious High Harbon Fly ash to 
Stabilize Recycled Pavement Materials as Pavement Base Material?, Proceedings 
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D.C. 
 
 32 
Wen, H., Warner, J., and Edil, T. (2008). ?Laboratory comparison of crushed aggregate 
and recycled pavement material with and without high-carbon fly ash?, 
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Washington, D.C. 
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 33 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
TABLES 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 34 
TABLE 1a. Index properties of the materials used in current study  
Classification 
Sample Cu Gs 
wopt 
(%) 
?d 
(kN/m3) 
LL 
(%) 
PI 
(%) 
Gravel 
Content 
(%) 
Fines Content 
(<75 ?m) 
(%) 
Fineness 
(>45 ?m) 
(%) 
 
USCS 
 
AASHTO 
BRG 25 2.52 8.0 20.4 NP NP 20 12 0 SP-SM A - 1 ? b (0) 
GAB 39 2.81 4.1 23.8 NP NP 45 4 0 SP A - 1 ? a (0) 
URM 6.7 2.64 13.4 18.8 NP NP 30 3 0 SP A - 1 ? b (0) 
BS 0.43 2.17 ? ? NP NP ? 91 25 ML A - 2 ? 4 (0) 
PS 11 2.2 ? ? NP NP ? 80 51 ML A - 2 ? 4 (0) 
DP 3.6 2.37 ? ? NP NP ? 79 34 ML A - 2 ? 4 (0) 
. 
 
 
TABLE 1b.  Chemical composition of the fly ashes.  Concentrations of major minerals were determined by X-ray fluorescence 
spectroscopy analysis.  All concentrations are in percentage by weight. 
 
Chemical Composition 
 
 
 
 
 
Fly ash 
 
LOI 
(%) 
 
SiO2 
(%) 
 
Al2O3 
(%) 
Fe2O3 
(%) 
CaO 
(%) 
K2O 
(%) 
TiO2 
(%) 
MgO 
(%) 
Na2O 
(%) 
Cr2O3 
(%) 
P2O5 
(%) 
SrO 
(%) 
BaO 
(%) 
BS 13.4 45.1 23.1 3.16 7.8 1.7 1.4 0.8 0.3 0.02 0.09 0.06 0.06 
PS 10.7 50.8 26.9 5.5 0.7 2.2 1.5 0.6 0.2 0.02 0.2 0.03 0.05 
DP 20.5 34.9 24.4 12.6 3.2 1.1 1.3 0.5 0.3 0.03 1.0 0.2 0.11 
BRG: Bank run gravel, GAB: Graded aggregate base, URM: Unpaved road material, PS: Paul Smith fly ash, DP: Dickerson Precipitator fly ash, BS: 
Brandon Shores fly ash, LOI: Loss on ignition.  Gs: Specific gravity, Cu: coefficient of uniformity, Cc: coefficient of curvature, woptm: optimum water 
content, ?dmax: maximum dry unit weight, LL: liquid Limit, PL: plastic limit, NP: Nonplastic.   
 
 35 
 
 
 
 
TABLE 2.  Legend and compositions of the mixtures. 
Legend of Mixtures 
Fly Ash 
Content 
(%) 
LKD Content 
(%) 
Optimum 
Water 
Content 
(%) 
Maximum 
Dry Unit 
Weight 
(kN/m3) 
BRG 0 0 8.0 20.4 
GAB 0 0 4.1 23.8 
URM 0 0 13.4 18.8 
10 BS + 2.5 LKD  10 2.5 10 19.2 
10 BS + 5 LKD  10 5 9.5 19.2 
20 BS + 2.5 LKD  20 2.5 10 18.5 
20 BS + 5 LKD  20 5 13 17.4 
10 PS + 2.5 LKD  10 2.5 9.0 18.8 
10 PS + 5 LKD  10 5 10 18.8 
20 PS + 2.5 LKD  20 2.5 12 17.3 
20 PS + 5 LKD  20 5 13 17.0 
10 DP + 2.5 LKD  10 2.5 9.0 19.1 
10 DP + 5 LKD  10 5 10 19.4 
20 DP +2.5 LKD  20 2.5 10 18.1 
20 DP + 5 LKD  20 5 12 18.0 
BS: Brandon Shores fly ash, PS: Paul Smith fly ash, DP: Dickerson Precipitator fly ash, LKD: 
Lime kiln dust, BRG:  Bank run gravel, GAB: Graded aggregate base, URM: Unpaved road 
gravel.  The numbers that follow the fly ashes and LKD indicate the percentages by weight of 
admixtures added to the soil.  
 
 
 36 
               TABLE 3.  Power model fitting parameters and measured plastic strains for resilient modulus tests. 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
LKD 
Content 
(%) 
K1 K2 ?plastic (%) K1 K2 ?plastic (%) K1 K2 ?plastic (%) 
  1-Day Cured or no curing for BRG, GAB and URM 7-Day Cured 28-Day Cured 
10 2.5 3260 0.57 0.83 6593 0.53 0.62 1412 0.93 0.49 
10 5 6470 0.49 0.67 3595 0.69 0.5 1636 0.81 0.49 
20 2.5 3260 0.57 0.74 1873 0.75 0.73 1300 0.84 0.63 
Brandon 
Shores  
20 5 85000 0.46 0.67 4225 0.59 0.59 36473 0.2 0.47 
10 2.5 5896 0.49 0.63 8193 0.43 0.61 10670 0.33 0.54 
10 5 6341 0.43 0.73 12410 0.41 0.4 16508 0.38 0.34 
20 2.5 6022 0.47 1.07 4904 0.52 0.66 3623 0.57 0.66 Paul Smith 
20 5 8158 0.42 0.83 12876 0.33 0.59 15629 0.32 0.49 
10 2.5 3220 0.61 0.76 3973 0.55 0.72 2047 0.87 0.44 
10 5 4768 0.56 0.59 4800 0.55 0.42 10310 0.53 0.29 
20 2.5 3169 0.62 0.7 8830 0.41 0.57 2689 0.72 0.54 
Dickerson 
Precipitator 
20 5 6500 0.49 0.56 11329 0.41 0.43 7367 0.54 0.4 
BRG 0 0 2450 0.60 1.0 - - - - - - 
GAB 0 0 7700 0.40 0.94 - - - - - - 
URM 0 0 1623 0.71 0.97 - - - - - - 
     LKD: Lime kiln dust
 
 37 
 
 
 
 
 
 
 
TABLE 4.  CBR and summary resilient modulus values 
 
Soil or Fly 
Ash Type 
Fly 
Ash 
Content 
(%) 
LKD 
Content 
(%) 
CBR (%) SMR (MPa) 
  1 Day 
Cured 
7 
Days 
Cured 
28 
Days 
Cured 
1 
Day 
Cured 
7 
Days 
Cured 
28 
Days 
Cured 
10 2.5 70 108 > 131 157 228 260 
10 5 73 142 > 156 179 245 274 
20 2.5 45 112 > 121 147 157 169 
Brandon 
Shores  
20 5 76 133 > 152 215 284 510 
10 2.5 83 115 > 120 189 230 243 
10 5 95 135 > 164 216 350 418 
20 2.5 34 71 100 172 198 207 Paul Smith 
20 5 60 87 >105 238 278 323 
10 2.5 44 69 > 120 174 180 277 
10 5 93 129 > 143 219 322 433 
20 2.5 65 84 111 183 217 243 
Dickerson 
Precipitator 
20 5 82 110 > 134 241 312 326 
BRG 0 0 27 130 
GAB 0 0 42 206 
URM 0 0 24 127 
 
BRG: Bank run gravel, GAB: Graded aggregate base, URM: Unpaved road gravel, LKD:   Lime kiln dust 
 
 
 38 
TABLE 5.  Chemical compositions of mixtures prepared with three different fly ashes 
Mixtures Prepared with BS                                            Mixtures Prepared with PS                                    Mixtures Prepared with DP                                            Chemical 
Constituents 
BS 
(%) 
PS 
(%) 
DP 
(%) 
Type I 
Portland 
Cement 
(%) 
Lime 
kiln dust 
(%) 10BS+ 
2.5L 
10BS+ 
5L 
20BS+ 
2.5L 
20BS+ 
5L 
10PS+ 
2.5L 
10PS+ 
5L 
20PS+ 
2.5L 
20PS+ 
5L 
10DP+ 
2.5L 
10DP+ 
5L 
20DP+ 
2.5L 
20DP+ 
5L 
SiO2  45.1 50.8 34.9 22 7.5 37.6 32.6 40.9 37.6 42.1 36.4 46 42.1 29.4 25.8 31.9 29.4 
Al2O3 23.1 26.9 24.4 5 2.7 19 16.3 20.8 19 22 18.8 24.2 22 20.1 17.2 22 20.1 
Fe2O3 3.2 5.5 12.6 3 1.1 2.7 2.5 2.9 2.7 4.6 4 5 4.6 10.3 8.8 11.3 10.3 
CaO 7.8 0.7 3.2 67 61.6 18.6 25.7 13.8 18.6 12.9 21 7.5 12.9 14.9 22.7 9.7 14.9 
MgO 0.8 0.6 0.5 1 2.5 1.2 1.4 1 1.2 1 1.2 0.8 1 0.9 1.2 0.7 0.9 
SiO2+ 
Al2O3  
+ Fe2O3 
71.4 83.2 71.9 30 11.3 59.3 51.3 64.7 59.3 68.8 59.2 75.2 68.8 59.8 51.7 65.2 59.8 
Silica Ratio 
(SR)  1.7 1.6 0.9 2.8 2 1.7 1.7 1.7 1.7 1.6 1.6 1.6 1.6 1 1 1 1 
LSF  0.05 0.006 0.03 1 2.6 0.1 0.2 0.1 0.1 0.1 0.2 0.05 0.1 0.1 0.2 0.1 0.1 
Alumina  
Ratio (AR) 7.3 4.9 1.9 1.7 2.5 6.9 6.6 7.1 6.9 4.8 4.7 4.8 4.8 2 2 1.9 2 
CaO/SiO2 0.2 0.01 0.1 3 8.2 0.5 0.8 0.3 0.5 0.3 0.6 0.2 0.3 0.5 0.9 0.3 0.5 
CaO/ 
(SiO2+Al2O3) 0.1 0.01 0.05 2.5 6 0.3 0.5 0.2 0.3 0.2 0.4 0.1 0.2 0.3 0.5 0.2 0.3 
LOI 13.4 10.7 20.5 0 26.7 16.1 17.8 14.9 16.1 13.9 16 12.5 13.9 21.7 22.6 21.2 21.7 
BS: Brandon Shores fly ash, PS: Paul Smith fly ash, DP: Dickerson Precipitator fly ash, L: Lime kiln dust (LKD), LOI: Loss of ignition, Silica ratio=SiO2/(Al2O3 + 
Fe2O3), LSF (Lime saturation factor) =CaO/(2.8 SiO2+1.2Al2O3+0.65Fe2O3) , Alumina ratio=Al2O3/Fe2O3   
 
 39 
 
 
 
 
 
 
 
 
TABLE 6.  Effect of freezing and thawing cycles on summary resilient moduli. 
Fly Ash Type 
Fly Ash 
Content 
(%) 
LKD 
Content 
(%) 
SMR (Mpa) 
 
Water Content 
(%) 
Number of Freeze and Thaw Cycles 0 4 8 12 0 4 8 12 
10 2.5 228 307 155 103 9 9 11 17 Brandon 
Shores  20 2.5 157 247 169 95 10 10 14 15 
10 5 350 340 222 165 9 11 14 15 Paul Smith 
20 5 278 245 105 93 13 13 16 22 
10 2.5 180 166 144 117 11 11 14 12 Dickerson 
Precipitator 10 5 217 218 158 152 11 10 18 15 
LKD: Lime kiln dust
 
 40 
 
 
TABLE 7.  Required base thickness for different mixture designs for two traffic and 
excellent drainage conditions (all thickness values are in mm). 
 
Based on CBR Based on MR Soil or 
 Fly Ash Type 
  
Fly Ash 
Content  
(%) 
LKD 
 Content 
(%) Case I Case II Case I Case II 
10 2.5 212 474 205 459 
10 5 176 395 192 431 
20 2.5 219 491 289 647 Brandon Shores  
20 5 198 445 176 395 
10 2.5 219 491 205 459 
10 5 176 395 159 356 
20 2.5 227 508 235 527 Paul Smith 
20 5 227 508 176 395 
10 2.5 219 491 265 594 
10 5 205 459 167 374 
20 2.5 223 501 227 508 
Dickerson 
Precipitator 
20 5 212 474 167 374 
BRG 0 0 382 846 335 750 
GAB 0 0 301 678 212 475 
URM 0 0 397 890 353 791 
BS: Brandon Shores fly ash, PS: Paul Smith fly ash, DP: Dickerson Precipitator fly ash, LKD: 
Lime kiln dust, BRG:  Bank run gravel, GAB: Graded aggregate base, URM: Unpaved road 
gravel.  The numbers that follow the fly ashes and LKD indicate the percentages by weight of 
admixtures added to the soil.  Minimum thickness requirement (AASHTO Guide 1993) for 
ESALs greater than 5,000,000 is 152.4 mm. 
 
 
a-) 
 
 41 
TABLE 8. Cost analysis for all mixture designs under excellent drainage conditions 
FlyAsh Type 
Fly Ash 
Content 
(%) 
Lime Kiln 
Dust 
Content 
(%) 
Thickness of the 
Base Layer (mm) 
Cost of Base 
Materials        
(x1000$) 
Cost of  LKD 
(x1000$) 
Cost of Fly Ash 
(x1000$) 
Total Cost of 
Construction 
(x1000$) 
  Case I Case II Case I Case II Case I Case II Case I Case II Case I Case II 
10 2.5 187 419 102.2 228.9 15.5 34.7 7.2 16.2 124.5 388.8 
10 5 182 407 101.9 228.1 30.0 67.3 5.6 12.6 137.5 433.0 
20 2.5 265 593 123.6 276.7 21.1 47.4 17.8 39.9 162.5 486.6 
Brandon 
Shores 
20 5 159 356 69.3 155.2 24.6 55.0 11.5 25.7 105.3 315.6 
10 2.5 193 432 102.2 228.8 15.5 34.7 16.3 36.5 134.0 397.5 
10 5 167 375 92.1 206.2 27.2 60.8 11.4 25.6 130.1 397.8 
20 2.5 227 509 100.8 225.8 17.3 38.7 32.7 73.2 150.8 415.3 Paul Smith 
20 5 177 396 75.2 168.5 26.6 59.7 28.0 62.8 130.0 358.1 
10 2.5 179 400 96.2 215.5 14.6 32.7 8.2 18.2 119.0 367.1 
10 5 167 375 95 212.8 28.0 62.8 6.2 14.0 129.3 404.9 
20 2.5 193 432 87.9 196.9 15.1 33.7 15.1 33.8 118.1 348.7 
Dickerson 
Precipitator 
20 5 177 396 78.9 176.9 28.0 62.6 15.6 34.9 122.5 362.0 
BRG 0 0 353 791 230.6 516.3 0 0 0 0 230.5 746.7 
GAB 0 0 318 712 233.3 522.5 0 0 0 0 233.3 755.8 
URM 0 0 398 890 252.4 565.3 0 0 0 0 252.2 565.4 
 
Note: Material cost includes only the material purchase, transportation, fuel and hauling costs. 
 
 
 42 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
FIGURES 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 43 
 
0
20
40
60
80
100
0.010.1110100
URM
VDOT Limits
BRG
GAB
Pe
rce
nt 
Fin
er 
(%
)
Particle Size (mm)
(a)
 
0
20
40
60
80
100
0.010.1110100
URM
AASHTO Limits
BRG
GAB
Pe
rce
nt 
Fin
er 
(%
)
Particle Size (mm)
(b)
 
FIGURE 1. Comparison of unpaved road material and the two materials used in base 
construction in Maryland to (a) VDOT base materials specification, and (b) AASHTO 
specification.  Note: URM: Unpaved road material, BRG : Bank Run Gravel, GAB: 
Graded aggregate base. 
 
 44 
 
0
5 0
1 0 0
1 5 0
1 7 2 8 1 7 2 8
2 . 5  %  L K D
5  %  L K D
Ca
lifo
rni
a B
ea
rin
g R
ati
o, 
CB
R
2 0 %  B S  b y  w e ig h t
1 0 %  B S  b y  w e ig h t
(a )
 
 
0
5 0
1 0 0
1 5 0
1 7 2 8 1 7 2 8
Ca
lifo
rni
a B
ea
rin
g R
ati
o, 
CB
R 2 0 %  P S  b y  w e ig h t
1 0 %  P S  
b y  w e ig h t
(b )
 
0
5 0
1 0 0
1 5 0
1 7 2 8 1 7 2 8
Ca
lifo
rni
a B
ea
rin
g R
ati
o, 
CB
R
C u r i n g  T i m e  ( d a y s )
2 0 %  D P  b y  w e ig h t
1 0 %  D P  b y  w e ig h t
(c )
 
FIGURE 2. Effect of curing time on CBR of mixtures prepared with (a) Brandon Shores 
fly ash, (b) Paul Smith fly ash, and (c) Dickerson Precipitator fly ash. 
 
 45 
      
       FIGURE 3. SEM photograph of (a) Brandon Shores fly ash, (b) unpaved road material amended with 10% Brandon 
Shores fly ash and 2.5% LKD by weight (10BS+2.5LKD), (c) Dickerson Precipitator fly ash, and (d) unpaved road 
material amended with 20% Dickerson Precipitator fly ash and 5% LKD by weight (20DP+5LKD).  All specimens 
were cured for 7 days. LKD: Lime kiln dust.
a-) 
(a) (b) 
(d) (c) 
20?m 
20?m 
1?m 
1?m 
 
 46 
 
(a) 
 (b) 
 
FIGURE 4.  EDX plot of the SEM photograph of (a) Dickerson Precipitator fly ash, and 
(b) 7-day cured unpaved road material amended with 20% Dickerson Precipitator fly ash 
and 5% LKD by weight (20DP+5LKD). 
 
 
 47 
20
40
60
80
100
120
140
160
180
0 1 2 3 4 5
10 BS 
20 BS
10 PS
20 PS
10 DP
20 DP
CB
R
LKD (%)
(a) r=0.75t=3.54
 
100
200
300
400
500
600
0 1 2 3 4 5
10 BS 
20 BS
10 PS
20 PS
10 DP
20 DP
SM
R 
(M
Pa
)
LKD (%)
(b)
r=0.76
t=3.75
 
FIGURE 5. Effect of LKD contents on (a) CBR and (b) SMR of 28-day cured specimens 
(Note: 10 BS, 20 BS, 10 PS, 20 PS, 10 DP, and 20 DP  designate the specimens with 
10% and 20% Brandon Shores, Paul Smith, and Dickerson Precipitator fly ash 
respectively. LKD: Lime Kiln Dust). 
 
 48 
90
100
110
120
130
140
150
160
170
5 10 15 20 25 30
C B
R
CaO Ratio (%)
R2 = 0.79
(a) 
r=0.89
t=6.13
 
90
100
110
120
130
140
150
160
170
0 0.2 0.4 0.6 0.8 1
C B
R
CaO/SiO2
R2 = 0.66
(b)
r=0.78
t=3.98
 
90
100
110
120
130
140
150
160
170
0 0.1 0.2 0.3 0.4 0.5 0.6
C B
R
CaO/(SiO2 + Al2O3)
R2 = 0.74
(c)
r=0.84
t=4.81
 
90
100
110
120
130
140
150
160
170
45 50 55 60 65 70 75 80
C B
R
Fineness (%)
(d)
r=0.34
t=1.16
 
FIGURE 6. Effect of (a) CaO content, (b) CaO/SiO2, (c) CaO/(SiO2 + Al2O3), and (d) fineness on CBR. 
 
 49 
90
100
110
120
130
140
150
160
170
0 0.05 0.1 0.15 0.2 0.25
C B
R
Silica Ratio (SR)
(a)
r=0.79
t=4.09
 
90
100
110
120
130
140
150
160
170
1 2 3 4 5 6 7 8
C B
R
Alumina Ratio, (AR)
(b)
r=0.22
t=0.72
 
90
100
110
120
130
140
150
160
170
0 0.1 0.2 0.3 0.4 0.5 0.6
C B
R
Lime Saturation Factor, (LSF)
(c)
r=0.17
t=0.55
 
90
100
110
120
130
140
150
160
170
0 5 10 15 20 25
C B
R
Fly ash (%)
(d)
r=-0.47
t=-1.68
 
FIGURE 7. Effect of (a) Silica ratio, (b) alumina ratio, (c) lime saturation factor, and (d) fly ash percentage on CBR. 
 
 50 
0
200
400
600
800
1000
30 40 50 60 70 80 90 100
Experimental
SM
R 
(M
Pa
)
CBR
SMR = 10.34 x CBR
SMR = 17.64 x CBR0.64
(a)
 
0
500
1000
1500
60 80 100 120 140 160
Experimental
SM
R 
(M
Pa
) 
CBR
SMR = 10.34 x CBR
SMR = 17.64 x CBR0.64
(b)
 
FIGURE 8.  CBR versus measured and predicted SMR for (a) 1 day cured specimens, and 
(b) 7 days cured specimens 
 
 51 
0
1 0 0
2 0 0
3 0 0
4 0 0
5 0 0
1 7 2 8 1 7 2 8
2 . 5  %  L im e  K i ln  D u s t  
5  %  L im e  K iln  D u s t
SM
R 
(M
Pa
)
2 0 %  B S  
b y  w e ig h t1 0 %  B S  b y  w e ig h t
a )
 
0
1 0 0
2 0 0
3 0 0
4 0 0
5 0 0
1 7 2 8 1 7 2 8
SM
R 
(M
Pa
)
20%  P S  b y w eig h t
10%  P S  b y w eig h t
b )
 
0
1 0 0
2 0 0
3 0 0
4 0 0
5 0 0
1 7 2 8 1 7 2 8
SM
R(
MP
a)
C u r in g  T im e  ( d a y s )
2 0 %  D P  b y  w e ig h t1 0 %  D P  b y  w e ig h t
c )
 
FIGURE 9. Effect of curing time on SMR of mixtures prepared with (a) Brandon Shores 
fly ash, (b) Paul Smith fly ash, and (c) Dickerson Precipitator fly ash. 
 
 
 52 
0
100
200
300
400
500
600
700
0 200 400 600 800 1000
10 PS + 2.5 LKD
10 PS + 5 LKD
20 PS + 2.5 LKD
20 PS + 5 LKD
Field Material
GAB
BRG
Re
sil
ien
t M
od
ulu
s M
R,
 (M
Pa
)
Bulk Stress (kPa)
(a)
 
 
 
0
200
400
600
800
1000
0 200 400 600 800 1000
10 DP + 2.5 LKD
10 DP + 5 LKD
20 DP + 2.5 LKD
20 DP + 5 LKD
Field Material
GAB
BRG
Re
sil
ien
t M
od
ulu
s, 
M R
 (M
Pa
)
Bulk Stress (kPa)
(b)
 
 
 
FIGURE 10. Resilient modulus of the 28-day cured specimens with varying bulk 
stresses: Mixtures prepared with (a) Paul Smith fly ash, and (b) Dickerson Precipitator fly 
ash 
 
 53 
150
200
250
300
350
400
450
500
550
5 10 15 20 25 30
S M
R 
( M
P a
)
CaO Ratio (%)
(a)
r=0.54
t=2.03
 
150
200
250
300
350
400
450
500
550
0 0.2 0.4 0.6 0.8 1
S M
R 
( M
P a
)
CaO/SiO2
(b)
r=0.56
t=2.11
 
150
200
250
300
350
400
450
500
550
0 0.1 0.2 0.3 0.4 0.5 0.6
S M
R 
( M
P a
)
CaO/(SiO2 + Al2O3)
(c)
r=0.54
t=2.05
 
150
200
250
300
350
400
450
500
550
45 50 55 60 65 70 75 80
S M
R 
( M
P a
)
Fineness (%)
(d)
r=0.04
t=0.12
 
FIGURE 11. Effect of (a) CaO content, (b) CaO/SiO2, (c) CaO/(SiO2 + Al2O3), and (d) fineness on SMR. 
 
 54 
150
200
250
300
350
400
450
500
550
0.8 1 1.2 1.4 1.6 1.8
S M
R 
( M
P a
)
Silica Ratio, (SR)
(a)
r=-0.09
t=-0.29
 
150
200
250
300
350
400
450
500
550
0 1 2 3 4 5 6 7 8
( S
M R
)  (
M P
a )
Alumina Ratio, (AR)
(b)
r=-0.09
t=-0.27
 
150
200
250
300
350
400
450
500
550
0 0.05 0.1 0.15 0.2 0.25
S M
R 
( M
P a
)
Lime Saturation Factor, (LSF)
(c)
r=0.48
t=1.71
 
150
200
250
300
350
400
450
500
550
0 5 10 15 20 25
S M
R 
( M
P a
)
Fly ash (%)
(d)
r=-0.11
t=-0.35
 
FIGURE 12. Effect of (a) Silica ratio, (b) alumina ratio, (c) LSF , and (d) fly ash percentage on SMR. 
 
 55 
0.2
0.4
0.6
0.8
1
1.2
1.4
1.6
0 2 4 6 8 10 12
10 BS + 2.5 LKD
20 BS + 2.5 LKD
10 PS + 5 LKD
20 PS + 5 LKD
SM
R 
Ra
tio
 = 
SM
Rn
/ S
M R
i
Freeze - thaw cycles
(a)
 
0.65
0.7
0.75
0.8
0.85
0.9
0.95
1
1.05
0 2 4 6 8 10 12
10 DP + 2.5 LKD
10 DP+ 5 LKD
SM
R 
Ra
tio
 = 
SM
Rn
/ S
M R
i
Freeze - thaw cycles
(b)
 
FIGURE 13.  Effect of freeze and thaw cycles on SMR values (Note: 10 BS, 20 BS, 10 
PS, 20 PS, 10 DP, and 20 DP  designate the specimens with 10% and 20% Brandon 
Shores, Paul Smith, and Dickerson Precipitator fly ash respectively. LKD: Lime Kiln 
Dust). 
 
 
 56 
 
 
0
5
1 0
1 5
2 0
2 5
10
 B
S 
+ 2
.5 
LK
D
20
 B
S 
+ 2
.5 
LK
D
10
 P
S 
+ 5
 LK
D
20
 P
S+
 5 
LK
D
10
 D
P 
+ 2
.5 
LK
D
10
 D
P 
+ 5
 LK
D
0  c y c le s
4  c y c le s
8  c y c le s
1 2  c y c le s
W
ate
r C
on
ten
t (%
)
 
 
 
 
 
 
 
 
FIGURE 14. Effects of freeze and thaw cycles on water contents (Note: 10 BS, 20 BS, 10 
PS, 20 PS, 10 DP, and 20 DP  designate the specimens with 10% and 20% Brandon 
Shores, Paul Smith, and Dickerson Precipitator fly ash respectively. LKD: Lime Kiln 
Dust). 
 
 
 
 
 
 
 
 57 
 
 
100
150
200
250
300
350
400
0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8
Case I
Case II
Su
mm
ary
 re
sil
ien
t m
od
ulu
s, 
SM
R 
(M
Pa
) 
Thickness, t (m)
SMR = 91.45t-1.23 
SMR = 33.84t-1.23 
 
 
 
FIGURE 15. Summary resilient modulus as a function of base layer thickness. 
 
 
 
 
 
 
 
 
 58 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
APPENDIX 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 59 
 
 
 
 
 
 
 
 
 
 
 
 
APPENDIX A 
 
 
 
 
CHEMICAL AND PHYSICAL PROPERTIES OF FLY ASHES USED IN THE 
CURRENT STUDY 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 60 
 
 
 
Table A.1 Properties of Maryland fly ashes with ASTM C 618 chemical and 
physical criteria for Class C and Class F fly ash. 
ASTM Requirements Chemical Requirements 
Class F Class C BS DP PS 
SiO2 + Al2O3 + Fe2O3, min 
(%) 70 50 71.4 71.9 83.2 
SO3, max (%) 5 5 - - - 
Moisture Content (as-
received), max (%) 3 3 1.8 7.7 3.5 
Loss on Ignition, max (%) 6 6 13.4 20.5 10.7 
      
      
ASTM Requirements Physical Requirements 
Class F Class C BS DP PS 
Fineness, max (%) 34 34 25 34 51 
Strength Activity @ 7 
Days, min (%) 75 75 - - - 
Strength Activity @ 28 
Days, min (%) 75 75 - - - 
Water Requirement, max 
(%) 115 115 - - - 
Autoclave Expansion, max 
(%) 0.8 0.8 - - - 
Density Variation, max (%) 5 5 - - - 
Variation of % Retained on 
45-?m filter, max (%) 5 5 - - - 
 
 
 
 
 
 
 
 61 
 
 
A 1. STATISTICAL ANALYSIS 
 
The relationship between CBR or resilient modulus and each of the fly ash chemical 
characteristics was tested for statistical significance by determining whether the Pearson 
correlation coefficient between CBR or resilient modulus and each of the fly ash 
variables is statistically different from zero.  For this statistical analysis, the t-statistic (t) 
is computed from the correlation coefficient (r) as: 
 
                                      
2
1 2
?
?
?=
n
r
rt ?                                                
 
where ? is the population correlation coefficient (assumed to be zero) and n is the number 
of degrees of freedom (24 for CBR test data and 20 for resilient modulus test data in this 
analysis).  A comparison then is made between t and the critical t (tcr) corresponding to a 
significance level ?.  If t > tcr, then the Pearson correlation coefficient is significantly 
different from zero and a significant relationship exists between CBR or resilient 
modulus and the fly ash property.  In this analysis, ? was set at 0.05 (the commonly 
accepted significance level), which corresponds to tcr = 2.06 for CBR test results and 
tcr=2.09 for resilient modulus test results. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 62 
 
 
 
 
 
 
 
 
 
 
 
 
 
APPENDIX B 
 
 
 
BASE COURSE TESTING PROTOCOL 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 63 
B.1 COMPACTION CURVES FOR ALL SPECIMENS 
17
18
19
20
21
22
23
24
25
0 5 10 15 20
URM
ZAV
GAB
BRG
Dr
y U
nit
 W
eig
ht 
(kN
 / m
3 )
Moisture Content (%)
(a)
Gs = 2.67
 
 
16
17
18
19
20
21
22
5 10 15 20
URM
ZAV
10 BS + 2.5 LKD
10 BS + 5 LKD
20 BS + 2.5 LKD
20 BS + 5 LKD
Dr
y U
nit
 W
eig
ht 
(kN
 / m
3 )
Moisture Content (%)
(b) Gs = 2.67
 
 
 64 
15
16
17
18
19
20
21
22
4 6 8 10 12 14 16 18 20
URM
ZAV
10 PS + 2.5 LKD
10 PS + 5 LKD
20 PS + 2.5 LKD
20 PS + 5 LKD
Dr
y U
nit
 W
eig
ht 
(kN
 / m
3 )
Moisture Content (%)
(c) Gs = 2.70
 
16
17
18
19
20
21
22
4 6 8 10 12 14 16 18
URM
ZAV
10 DP + 2.5 LKD
10 DP + 5 LKD
20 DP + 2.5 LKD
20 DP + 5 LKD
Dr
y U
nit
 We
igh
t (k
N 
/ m
3 )
Moisture Content (%)
(d) Gs = 2.69
 
Figure B. 1 Compaction curves for (a) conventional base materials, (b) mixtures prepared 
with Brandon Shores fly ash, (c) mixtures prepared with Paul Smith fly ash, and (d). 
mixtures prepared with Dickerson Precipitator fly ash (Note: 10 BS, 20 BS, 10 PS, 20 PS, 
10 DP, and 20 DP  designate the specimens with 10% and 20% Brandon Shores, Paul 
Smith, and Dickerson Precipitator fly ash respectively. LKD: Lime Kiln Dust, GAB: 
Graded Aggregate Base, RGB: Bank Run Gravel). 
 
 65 
B.2 RESILIENT MODULUS TEST PROTOCOL AND LOADING SEQUENCE 
SUMMARY TABLE  
 
 
The resilient modulus test procedure was based on the AASHTO T 307-99 a protocol 
for testing base and highway base and subbase materials. The specimens of 101.6 mm 
in diameter and 230.2 mm in height were compacted in split molds at their OMC in 
eight layers using the standard Proctor energy. The deformation was measured 
externally with two spring-loaded linear variable differential transducers (LVDT).  A 
Geocomp LoadTrac-II loading frame and associated hydraulic power unit system was 
used to load the specimens.  Conditioning stress was 103 kPa.  Confining stress was 
kept between 20.7 and 138 kPa during loading stages, and the deviator stress was 
increased from 20.7 kPa to 276 kPa and applied 100 repetitions at each step.   The 
loading sequence, confining pressure, and data acquisition were controlled by a 
personal computer equipped with RM 5.0 software. The base and subbase testing 
sequence is shown in Table B.1 
 The resilient modulus of soil was computed by using the common model defined 
by Moosazadh and Witczak (1981).  A summary resilient modulus (SMR) was 
computed at a bulk stress of 208 kPa, following the suggestions provided in NCHRP 
1-28A. 
 
 
 
 
 
 
 
 
 
 
 
 
 
 66 
 
 
 
Table B.1 AASHTO T 307-99 resilient modulus testing sequence for base and 
subbase materials. 
Sequence 
No. 
Confining 
Pressure, 
S3 (kPa) 
Maximum 
Axial 
Stress, Smax 
(kPa) 
Cyclic 
Stress, 
Scyclic 
(kPa) 
Constant 
Stress, 
0.1 Smax 
(kPa) 
Cycles 
0 103.4 103.4 93.1 10.3 500 
1 20.7 20.7 18.6 2.1 100 
2 20.7 41.4 37.3 4.1 100 
3 20.7 62.1 55.9 6.2 100 
4 34.5 34.5 31 3.5 100 
5 34.5 68.9 62 6.9 100 
6 34.5 103.4 93.1 10.3 100 
7 68.9 68.9 62 6.9 100 
8 68.9 137.9 124.1 13.8 100 
9 68.9 206.8 186.1 20.7 100 
10 103.4 68.9 62 6.9 100 
11 103.4 103.4 93.1 10.3 100 
12 103.4 206.8 186.1 20.7 100 
13 137.9 103.4 93.1 10.3 100 
14 137.9 137.9 124.1 13.8 100 
15 137.9 275.8 248.2 27.6 100 
 
 
 
 
 
 
 
 
 
 
 
 67 
 
B.3 STEP-BY-STEP RESILIENT MODULUS TEST PROCEDURE 
1) Turn on Geocomp Load Trac II  
2) Turn the air pressure pump on 
3) Measure the specimen height and diameter 
4) Place the porous stone on bottom plate 
5) Place the filter paper on bottom porous stone 
6) Place the specimen on bottom plate 
7) Place the filter paper on top of the specimen 
8) Place the porous stone on filter paper 
9) Place the top plate on top of the specimen 
10) Place rubber membrane over specimen using a mold 
11) Place two O- rings on both bottom and top of the plates to hold the membrane in 
place 
12) Plug the drainage tubes on top plate. 
13) Place the cell on bottom cap 
14) Place cover plate, it should not be tight 
15) Place LVDT on top of chamber 
16) Screw cover plate with three rods carefully 
17) Plug air supply hose into cell 
18) Log into PC and open the Resilient modulus RM version 5.0 software 
19) Input Specimen height, diameter, and weight. 
20) Input the loading and pressure data which is designed for base and subbase test 
protocol 
21) Click on the load calibration menu and check the applied load with the load data that 
you entered 
22) Click run test and save the file. 
 
 
 
 
 
 68 
 
B.4 RESILIENT MODULUS TEST APPARATUS 
 
 
 
Figure B.2 Photo of Resilient Modulus Testing Equipment 
 
 
 
 69 
 
B.5 PHOTOS OF SOIL SAMPLES  
 
 
 
 
 
 
 
Figure B.3. GAB (a), URM (b), and BRG (c) 
(Note: GAB: Graded aggregate Base, URM: Unpaved road material, BRG: Bank run gravel.) 
 
 
 
 
 
 
(a) (b) 
(c) 
 
 70 
 
 
 
 
 
 
 
 
 
 
APPENDIX C 
 
 
 
 
 
CBR AND RESILIENT MODULUS TEST RESULTS 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 71 
C1. CBR VERSUS MEASURED SMR  
140
160
180
200
220
240
260
30 40 50 60 70 80 90 100
SM
R 
(M
Pa
)
CBR
(a)
R2 = 0.33
 
150
200
250
300
350
400
60 80 100 120 140 160
SM
R 
(M
Pa
)
CBR
(b)
R2 = 0.32
 
Figure C.1. CBR versus measured SMR vs. CBR graph for (a)1 day cured 
specimens, and (b) 7 days cured specimens.
 
 72 
C2. CBR VERSUS PREDICTED SMR  
 
Table C.1. Predicted SMR values based on CBR values 
Fly Ash Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
CBR SMR (Mpa)                     (SM
R = 10.34 x CBR) 
SMR (Mpa)                     
(SMR = (17.64 x CBR0.64) 
  1 Day Cured 7 Days Cured 1 Day Cured 7 Days Cured 1 Day Cured 7 Days Cured 
10 3 70 108 724 1117 267 353 
10 5 73 142 755 1468 275 420 
20 3 45 112 465 1158 201 361 
Brandon 
Shores 
20 5 76 133 786 1375 282 403 
10 3 83 115 858 1189 298 367 
10 5 95 135 982 1396 325 407 
20 3 34 71 352 734 168 270 Paul Smith 
20 5 60 87 620 900 242 307 
10 3 44 69 455 713 199 265 
10 5 93 129 962 1334 321 395 
20 3 65 84 672 869 255 300 
Dickerson 
Precipitator 
20 5 82 110 848 1137 296 357 
GAB 0 0 42 434 193 
BRG 0 0 27 279 145 
URM 0 0 24 248 135 
 
 
 73 
 
 
 
 
 
 
 
 
 
 
APPENDIX D 
 
 
 
BASE THICKNESS CALCULATIONS FOR SPECIMENS SUBJECTED TO 
FREEZE-THAW 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 74 
 
D.1 BASE THICKNESS CALCULATIONS FOR SPECIMENS SUBJECTED TO 
FREEZE-THAW 
 
 
 
Table D.1. Base thickness values based on SMR values for traffic case I (all thickness 
values are in mm) 
Base thickness values based on SMR values Specimen Name 
Cycle Number 
  0 4 8 12 
10 BS + 2.5 LKD 205 318 530 530 
20 BS + 2.5 LKD 289 265 530 530 
10 PS + 5 LKD 159 223 289 289 
20 PS + 5 LKD 176 454 454 578 
10 DP + 2.5 LKD 265 318 318 454 
10 DP + 5 LKD 167 289 289 302 
 
 
 
 
 
Table D.2. Base thickness values based on SMR values for traffic case II (all thickness 
values are in mm) 
Base Thickness values based on SMR values Specimen Name 
Cycle Number 
  0 4 8 12 
10 BS + 2.5 LKD 459 712 1186 1186 
20 BS + 2.5 LKD 647 593 1186 1186 
10 PS + 5 LKD 356 501 647 647 
20 PS + 5 LKD 395 1017 1017 1294 
10 DP + 2.5 LKD 593 712 712 1017 
10 DP + 5 LKD 374 647 647 678 
BS: Brandon Shores fly ash, PS: Paul Smith fly ash, DP: Dickerson Precipitator fly ash, LKD: 
Lime kiln dust. The numbers that follow the fly ashes and LKD indicate the percentages by 
weight of admixtures added to the soil.  Minimum thickness requirement (AASHTO Guide 1993) 
for ESALs greater than 5,000,000 is 152.4 mm. 
 
 
 
 75 
 
100
200
300
400
500
600
0 2 4 6 8 10 12
10 BS + 2.5 LKD
20 BS + 2.5 LKD
10 PS + 5 LKD
20 PS + 5 LKD
10 DP + 2.5 LKD
10 DP + 5 LKD
Ba
se
 Th
ick
ne
ss
 (m
m)
Number of Freeze and Thaw Cycles
(a) 
 
200
400
600
800
1000
1200
1400
0 2 4 6 8 10 12 14
10 BS + 2.5 LKD
20 BS + 2.5 LKD
10 PS + 5 LKD
20 PS + 5 LKD
10 DP + 2.5 LKD
10 DP + 5 LKD
Ba
se
 Th
ick
ne
ss
 (m
m)
Number of Freeze and Thaw Cycles
(b) 
 
Figure D.1 Required thickness vs. number of freeze and thaw cycles (a) for traffic case I, 
and (b) for traffic case II 
 
 76 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
 
APPENDIX E 
 
 
 
BASE THICKNESS AND COST CALCULATIONS FOR SPECIMENS UNDER 
DIFFERENT DRAINAGE CONDITIONS  
 
 
 
 
 
 
 
 
 77 
E.1 BASE THICKNESS CALCULATIONS FOR SPECIMENS UNDER 
DIFFERENT DRAINAGE CONDITIONS 
 
 
 
 
Table E1. Required base thickness for different mixture designs for two traffic conditions 
under good drainage conditions (all thickness values are in mm). 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of the 
Base Layer Based 
on CBR 
Thickness of the 
Base Layer Based 
on SMR 
  Case I Case II Case I Case II 
10 2.5 277 555 277 555 
10 5 262 524 269 539 
20 2.5 314 629 392 787 
Brandon 
Shores 
20 5 262 524 235 472 
10 2.5 314 629 285 572 
10 5 262 524 248 497 
20 2.5 336 674 336 674 Paul Smith 
20 5 332 665 262 524 
10 2.5 314 629 265 530 
10 5 269 539 248 497 
20 2.5 327 656 285 572 
Dickerson 
Precipitator 
20 5 277 555 262 524 
BRG 0 0 523 1049 589 1180 
GAB 0 0 428 858 471 944 
URM 0 0 673 1349 589 1180 
 
 
 
 
 
 
 
 
 78 
 
 
 
 
 
 
Table E2. Required base thickness for different mixture designs for two traffic conditions 
under fair drainage conditions (all thickness values are in mm). 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of the 
Base Layer Based 
on CBR 
Thickness of the 
Base Layer Based 
on SMR 
    Case I Case II Case I Case II 
10 2.5 412 760 412 760 
10 5 389 718 400 738 
20 2.5 467 861 584 1076 
Brandon 
Shores 
20 5 389 718 350 646 
10 2.5 467 861 424 783 
10 5 389 718 369 680 
20 2.5 500 923 500 923 Paul Smith 
20 5 493 910 389 718 
10 2.5 467 861 393 726 
10 5 400 738 369 680 
20 2.5 486 897 424 783 
Dickerson 
Precipitator 
20 5 412 760 389 718 
BRG 0 0 778 1435 875 1614 
GAB 0 0 637 1174 700 1292 
URM 0 0 1000 1845 875 1614 
 
 
 
 
 
 
 
 
 79 
 
 
 
Table E3. Required base thickness for different mixture designs for two traffic conditions 
under poor drainage conditions (all thickness values are in mm). 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of the 
Base Layer Based 
on CBR 
Thickness of the 
Base Layer Based 
on SMR 
    Case I Case II Case I Case II 
10 2.5 637 1101 637 1101 
10 5 601 1039 619 1069 
20 2.5 722 1247 902 1559 
Brandon 
Shores 
20 5 601 1039 541 935 
10 2.5 722 1247 656 1134 
10 5 601 1039 570 985 
20 2.5 773 1336 773 1336 Paul Smith 
20 5 762 1318 601 1039 
10 2.5 722 1247 608 1051 
10 5 619 1069 570 985 
20 2.5 752 1299 656 1134 
Dickerson 
Precipitator 
20 5 637 1101 601 1039 
BRG 0 0 1203 2079 1353 2339 
GAB 0 0 984 1701 1083 1871 
URM 0 0 1547 2673 1353 2339 
 
 
 
 
 
 80 
Table E4. Cost Analysis for different mixture designs for two traffic conditions under good drainage conditions (all thickness values 
are in mm). 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of 
the Base Layer 
(mm) 
Cost of Base 
Materials 
(x1000$) 
Cost of  LKD 
(x1000$) 
Cost of Fly Ash 
(x1000$) 
Total Cost of 
Construction 
(x1000$) 
  Case I Case II Case I Case II Case I Case II Case I Case II Case I Case II 
10 2.5 277 555 151.3 303.3 229.6 46.0 10.7 21.5 185.0 534.4 
10 5 269 539 150.8 302.4 445.0 89.2 8.3 16.7 203.7 595.2 
20 2.5 392 787 183.0 366.7 313.4 62.8 26.4 52.9 240.7 670.3 
Brandon 
Shores 
20 5 235 472 102.7 205.8 363.4 72.8 17.0 34.1 156.0 434.6 
10 2.5 285 572 151.3 303.2 229.5 46.0 24.2 48.4 198.4 547.6 
10 5 248 497 136.4 273.4 402.3 80.6 16.9 33.9 193.5 547.5 
20 2.5 336 674 149.3 299.3 255.8 51.3 48.4 97.1 223.3 573.9 Paul Smith 
20 5 262 524 111.4 223.4 394.5 79.1 41.5 83.1 192.4 494.8 
10 2.5 265 530 142.5 285.6 216.1 43.3 12.0 24.1 176.1 505.0 
10 5 248 497 140.7 282.1 415.1 83.2 9.30 18.5 191.5 556.8 
20 2.5 285 572 130.2 261.0 223.0 44.7 22.3 44.8 174.8 480.5 
Dickerson 
Precipitator 
20 5 262 524 117.0 234.4 414.0 83.0 23.1 46.2 181.4 498.8 
BRG 0 0 523 1049 341.4 684.4 0 0 0 0 341.4 102.6 
GAB 0 0 471 944 345.5 692.5 0 0 0 0 345.5 103.8 
URM 0 0 589 1180 373.8 749.4 0 0 0 0 373.8 749.4 
 
 81 
 
Table  E5. Cost Analysis for different mixture designs for two traffic conditions under fair drainage conditions (all thickness values 
are in mm). 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of 
the Base Layer 
(mm) 
Cost of Base 
Materials 
(x1000$) 
Cost of  LKD 
(x1000$) 
Cost of Fly Ash 
(x1000$) 
Total Cost of 
Construction 
(x1000$) 
  Case I Case II Case I Case II Case I Case II Case I Case II Case I Case II 
10 2.5 412 760 225.0 303.3 34.2 63.0 16.0 29.4 275.2 641.5 
10 5 389 738 218.1 302.4 64.3 122.1 12.0 22.8 294.4 718.8 
20 2.5 467 1076 217.7 366.8 37.3 86.0 31.4 72.3 286.3 739.0 
Brandon 
Shores 
20 5 389 646 169.6 205.8 60.0 99.7 28.1 46.6 257.7 563.1 
10 2.5 467 783 247.5 303.2 37.6 63.0 39.5 66.2 324.5 690.7 
10 5 389 680 214.1 273.4 63.2 110.3 26.6 46.4 303.8 687.5 
20 2.5 500 923 222.1 299.3 38.0 70.2 72.0 132.8 332.1 701.6 Paul Smith 
20 5 493 718 210.1 223.4 74.4 108.2 78.2 113.8 362.6 694.2 
10 2.5 467 726 251.4 285.6 38.2 59.3 21.2 33.0 310.8 655.7 
10 5 400 680 227.2 282.1 67.0 113.9 14.9 25.4 309.1 705.1 
20 2.5 486 783 221.8 261.0 38.0 61.2 38.1 61.3 297.9 620.0 
Dickerson 
Precipitator 
20 5 412 718 184.1 234.4 65.2 113.6 36.3 63.2 285.6 633.5 
BRG 0 0 778 1435 507.7 684.4 0 0 0 0 507.7 1192.1 
GAB 0 0 637 1292 467.1 692.5 0 0 0 0 467.1 1159.6 
URM 0 0 1000 1614 635.4 749.4 0 0 0 0 635.3 749.4 
 
 
 82 
 
Table  E6. Cost Analysis for different mixture designs for two traffic conditions under poor drainage conditions (all thickness values 
are in mm). 
 
 
 
Fly Ash 
Type 
Fly Ash 
Content 
(%) 
Lime 
Kiln 
Dust 
Content 
(%) 
Thickness of 
the Base Layer 
(mm) 
Cost of Base 
Materials ($) 
Cost of  LKD 
($) 
Cost of Fly Ash 
($) 
Total Cost of 
Construction ($) 
  Case I Case II Case I Case II Case I Case II Case I Case II Case I Case II 
10 2.5 637 1101 347.9 601.3 52.8 91.2 24.7 42.7 425.360 1117.8 
10 5 619 1069 346.8 599.3 102.3 176.8 19.1 33.1 468.184 1244.3 
20 2.5 902 1559 420.6 726.9 72.1 124.5 60.6 104.8 553.300 1404.7 
Brandon 
Shores 
20 5 541 935 236.0 407.8 83.5 144.4 39.1 67.5 358.566 910.8 
10 2.5 656 1134 347.8 601.0 52.8 91.2 55.5 95.9 456.056 1148.3 
10 5 570 985 313.5 541.8 92.5 159.8 38.9 67.3 444.906 1146.6 
20 2.5 773 1336 343.3 593.3 58.8 101.6 111.3 192.4 513.416 1208.3 Paul Smith 
20 5 601 1039 256.2 442.7 90.7 156.7 95.4 164.9 442.247 1041.7 
10 2.5 608 1051 327.5 566.0 49.7 85.9 27.7 47.8 404.890 1056.8 
10 5 570 985 323.5 559.1 95.4 164.9 21.3 36.7 440.203 1164.2 
20 2.5 656 1134 299.3 517.2 51.3 88.6 51.4 88.8 401.939 1007.8 
Dickerson 
Precipitator 
20 5 601 1039 268.8 464.6 95.2 164.5 53.0 91.6 416.995 1046.1 
BRG 0 0 1203 2079 784.9 1356.5 0 0 0 0 784.887 2141.4 
GAB 0 0 1083 1871 794.3 1372.7 0 0 0 0 794.246 2166.9 
URM 0 0 1353 2339 859.4 1485.2 0 0 0 0 859.415 1485.3 
 
 83 
10 BS + 2.5 LKD
10 BS + 5 LKD
GAB                       ........
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
Time to drain water from the base layer (days)
Quality of Drainage
a)
T o
t a l
 C
o s
t  x
 1 0
0 , 0
0 0
 $
Case II Traffic Conditions
 
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
Time to drain water from the base layer (days)
Quality of Drainage
T o
t a l
 C
o s
t   X
 1 0
0 , 0
0 0
 $
20 PS + 2.5 LKD
20 PS + 5 LKD
GAB                       ........
(b)
Case II Traffic Conditions
 
10 DP + 2.5 LKD
10 DP + 5 LKD
GAB                       ..........
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
Time to drain water from the base layer (days)
Quality of Drainage
T o
t a l
 C
o s
t  X
 1 0
0 ,0
0 0
 $
(c)
Case II Traffic Conditions
 
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
Time to drain water from the base layer
Quality of Drainage
10 DP + 2.5 LKD
GAB                       ..........
Case II 
Case I 
T o
t a l
 C
o s
t   X
 1 0
0 , 0
0 0
 $
(d)
 
10 BS + 2.5 LKD
 GAB                      ..........
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
Time to drain water from the base layer (days)
Quality of Drainage
T o
t a l
 C
o s
t  x
 1 0
0 , 0
0 0
 $
Case II
Case I(e)
 
0
5
10
15
20
25
0.0833 1 7 10
Excellent Good Fair Poor
T o
t a l
 C
o s
t  x
 1 0
0 , 0
0 0
 $
Time to drain water from the base layer (days)
Quality of Drainage
20 DP + 2.5 LKD
GAB . . . . . . 
Case II 
Case I 
(f)
 
FigureE.1. Effect of LKD addition (a),(b),(c) and traffic conditions(d), (e), (f) on total construction fee of the highway base layer. BS: Brandon Shores fly ash, PS: Paul Smith fly ash, DP: Dickerson 
Precipitator fly ash, LKD: Lime kiln dust. The numbers that follow the fly ashes and LKD indicate the percentages by weight of admixtures added to the soil. 
 
 84 
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