ABSTRACT
Title of thesis: PHYSICAL AND POTENTIOMETRIC CONSTANT OF 
FERROUS AND FERRIC PHYTATE APPLIED TO 
ORGANIC PHOSPHATE TRANSPORT IN POORLY 
DRAINED SOIL
Lynne Heighton, Master of Science, 2005
Thesis directed by: Assistant Professor Ronald L. Siefert
Department of Marine, Estuarine and Environmental 
Science
Inositol phosphates are metabolically derived organic phosphates that increasingly 
appear to be an important sink and source of phosphate in the environment.  Inositol 
hexakis dihydrogen phosphate or phytic acid is the most common inositol phosphate in 
the environment.  Iron is abundant in many terrestrial systems.  Mobility of phytic acid 
iron complexes are potentially pH and redox responsive.  Ferric and ferrous complexes of 
phytic acid were investigated by proton nuclear magnetic resonance spectroscopy, 
enzymatic dephosphoralation and potentiometrically in solution.  The redox potential and 
concentration of iron were measured in a soil column containing a benchmark poorly 
drained soil from Maryland (Elkton).   Ferrous phytate was found to form quickly and 
persist for a longer period then ferric phytate.  Dissociation constants were 1.113 and 
1.186 and formation constants were 0.899 and 0.843 for ferric and ferrous phytate 
respectively.    Enzymatic dephosphoralation recoveries supported the magnitude of the 
kinetic and equilibrium rate constants.   
PHYSICAL AND POTENTIOMETRIC CONSTANT OF FERROUS AND FERRIC 
PHYTATE APPLIED TO ORGANIC PHOSPHATE TRANSPORT IN POORLY 
DRAINED SOIL. 
By
Lynne Heighton
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
2005
Advisory Committee:
Assistant Professor Ronald L. Siefert, Chair
Professor Jeffery Cornwell
Dr. Walter F. Schmidt
?Copyright by
Lynne Heighton
2005
ii
Table of Contents
List of Tables..?????????????????????????????iii
List of Figures...????????????????????????????..iv
Introduction ??????????????????????????????.1
Chapter I: Speciation of Phytate is pH Dependent?????????????...5
Methods????????????????????????????...7
Results and Discussion??????????????????????....8
Chapter II: Kinetic and Equilibrium Constants of Phytic Acid, Ferric and 
Ferrous Phytate derived from Nuclear Magnetic Resonance 
Spectroscopy???????????????????????..11
Introduction???????????????????????????11
Materials and Methods??????????????????????...15 
 Nuclear Magnetic Resonance?????????????????15
Kinetic and Equilibrium Calculations from NMR Spectra??????15
Enzymatic Analysis????????????????????...16
Statistical Analysis?????????????????????17
Results????????????????????????????...18
Constants derived from Nuclear Magnetic Resonance Spectra????18
Enzymatic dephosphorolation????????????????...21
Discussion???????????????????????????..22
Conclusion???????????????????????????.25
Appendix I: Potentiometric measurement of ferric and ferrous species in soil 
columns containing Elkton soil series, Queen Anne County, 
Maryland?????????????????????????28
Abstract to Appendix I..??????????????????????.28
Introduction???????????????????????????28
Materials and Methods??????????????????????...32
Platinum electrode construction..........................................................?...33
Soil columns???????????????????????..33
Soil Selection?.??????????????????????34
Potentiogram Analysis??????????????????...?34
Results?????????????????????????????35
Discussion???????????????????????????..38
Conclusions ?????????????????????????????...40
References??????????????????????????????..43
iii
List of Tables
Table 1 Results of enzymatic dephosporalation of phytic acid 
and ferrous and ferric complexes of phytic acid  ..?????????22
Table 2 Soil Column effluent collected every four hours over a 
three day period  ??????????????????????36
iv
List of Figures
Figure 1   Speciation of myo-inositol hexakis dihydrogen 
phosphate (phytic acid) from acid dissociation 
constants (pKa)  ??????????????????????6
Figure 2   Structure of myo-inositol-1, 2, 3, 4, 5, 6-hexakis
dihydrogen phosphate or more commonly known as 
phytic acid (C
6
H
18
P
6
O
24
)  ??????????????????..12
Figure 3 Proton nuclear magnetic resonance (1H NMR) of
phytic acid  ????????????????????????19
Figure 4 Proton NMR spectra of ferric and ferrous iron 
complexes of phytic acid   ??????????????????20
Figure 5 Ratio of the concentration of ferric to ferrous species
as a function of pH .. ????????????????????.36
Figure 6 Oxidation reduction potential of the ferrous ferric couple 
at three levels within the Elkton Soil column over a period 
of four days  ???????????????????????..37
Figure 7 Examples of potentiograms from column effluent   ????????.38
1
Introduction
Phosphorus, one of the macro nutrients necessary for all life is present in most 
cells between 2-4% on a dry weight basis (Karl, 2000).  The role of phosphorus 
ecologically is unchallenged, but for a variety of reasons its biogeochemical cycle is not 
completely understood.  The integral part that phosphorus plays in biological processes 
complicates identification of organic phosphorus species, their environmental 
concentration and their persistence in the environment.  The flux of inorganic phosphates 
to organic phosphorus species is biologically driven and ubiquitous.  In many fresh water 
systems phosphorus concentration are too small to be accurately measured.  Often surface 
waters participating in photosynthesis are isolated from phosphorus rich bed sediments 
by thermo clines.  In such instances measuring the phosphate ion organic phosphate flux 
generated by biological activities is below instrumental detection limit (Hudson, 2000).  
Hudson, 2000 found that in measurements of 56 North American lakes that 
phosphate levels were two to three times lower then previously thought.  Phosphate 
concentrations of 50 pM or less were capable of sustaining an efficient and thriving 
microbial community.  Hudson, 2000 and Karl, 2000 in separate papers interpreted these 
findings as trace phosphate levels in fresh water systems are the historical norm and rapid 
microbial turnover times are ecologically more important then the quantity of phosphate 
present in the system. 
Clark et al, 1998 found that by using 
31
P nuclear magnetic resonance and 
tangential-flow ultrafiltration in a marine environment that two major classes of high 
molecular weight phosphorus compounds were associated with dissolved organic matter, 
phosphorus esters and phosphonates.  In marine surface waters the phosphorus esters 
2
were depleted when compared to the phosphonates but as the dissolved organic matter 
moved down the water column ratios stabilized and were approximately equal at depths.  
They further found that phosphorus was depleted from dissolved organic matter and that 
the carbon to phosphorus and nitrogen to phosphorus ratios increased indicating that 
phosphorus is the limiting nutrient in oligotrophic marine surface waters and that rapid 
cycling is ecologically more important then the quantity of  phosphorus in the system.  
Mono-phosphates have been found to be the primary organic species in soils but 
diesters and phosphonates are also found in soils or added to soil as animal manures, bio-
solids or pesticides (Clark et al, 1998; Brinch-Pedersen et al, 1998).  Inorganic 
phosphorus is a mineral bound element with very little atmospheric transport contribution 
to its cycle.  A sometimes notable exception is atmospheric transport of phosphorus as 
particle associated dust (Brinch-Pedersen et al, 2002).  Mineral phosphorus is accessed by 
the plant community as phosphate ion.  Strategies to dissolve mineral phosphate stores 
involve weathering of parent rock containing phosphorus and acidification of plant root 
zones by plants and fungi able to excrete organic acids from their roots thus dissolving 
phosphate containing mineral stores (Brady and Weil, 2002).
The primary transport processes of the phosphorus cycle involve non-point source 
movement from soil systems to surface waters.  The major non-point source transport 
mechanisms are believed to be overland flow processes.  Erosion driven movement of 
sediment bound phosphorus and flood water containing dissolved phosphates are 
believed to contribute the majority of phosphorus to surface waters (Butler and Coale, 
2005; Sims et al, 1988).  Other non-point source transport processes involve leaching of 
phosphorus in soil pore water to surface waters.    Factors controlling phosphorus 
3
movement into the dissolved phase include the oxidation reduction potential, the amount 
and type of clay present in the soil and the fraction of phosphorus present as an organic 
phosphorus species (Young and Ross, 2001; Turner and Haygarth, 2001; Sims et al, 
1998; Anderson, 1980; Cosgrove, 1977). 
Undoubtedly, anthropological activities have played a major role in transporting 
phosphorus from mineral deposits to surface waters.  The unprecedented acceleration of 
food production can in part be contributed to phosphorus mining and redistribution as 
fertilizer.  Crops utilize about 10% of the mineral fertilizers applied to them; the 
remainder is thought to be complexed in the soil and to have differing degrees of 
availability depending on factors such as soil organic content, clay content, pH and 
temperature (Cosgrove, 1977). The concentration of livestock production to relatively 
small geographical areas has lead to concurrent increases in manure production.  It is 
economically unfeasible to transport the manure away from these centers of agricultural
livestock production and the quantity of manure generated frequently exceeds the 
cropping needs of the area leading to stockpiling and composting of manures rich in 
organic phosphorus (Brinch-Pedersen et al, 2002; Sims, 1998; Gburek et al, 1996).  
The parameters that govern fate and transport of phosphorus in soil systems are 
the subject of great scrutiny due to the impact of phosphorus on surface water quality.  
Because of the work done by Karl, Hudson, Clark and others trace levels of phosphorus 
in aquatic environments is likely the healthy norm in many if not all aquatic ecosystems.  
Understanding the entire biogeochemical cycle of phosphorus not just the primary 
transport processes is essential to management practices that will ensure food production 
and concurrently protect water quality.
4
Although, phosphorus transport by subsurface leaching is not thought to be the 
primary transport mechanism in soil systems, it is likely an important contributor in many
geographic areas.  Investigation of phosphorus movement by subsurface leaching in areas 
that are stockpiling manures or have historically over fertilized for phosphorus, have a
flat landscape that does not rapidly drain, contains some clay, and readily support 
reducing conditions may be important contributors of phosphorus to surface waters.   
Organic phosphorus has been a traditionally neglected pool in the phosphorus 
budget.  Understanding the fate and transport of organic phosphorus is a critical 
component to the understanding its environmental role and impact on the phosphorus 
cycle.   The monophosphate phytic acid is acknowledged to be the major form of organic 
phosphorus in soil systems and manures (Jayasundera, S et al. 2005; Hansen et al. 2004; 
Turner et al, 2003).  Phytic acid is not responsive to oxidation reduction reactions itself 
but it will form complexes with metals that are redox responsive.    
The goals of this thesis were to investigate phytic acid by using published acid 
disassociation constants (pKa) to generate the fractional species change due to changes in 
pH. Phytic acid formation constants for ferric and ferrous iron were also derived from 
proton nuclear magnetic resonance spectra (H-NMR).  The magnitudes of the H-NMR 
derived constants were supported by measuring the phosphate recovered from the 
enzymatic dephosphoralation of phytic acid using the enzyme phytase. Ferrous and ferric 
iron speciation was measured potentiometrically and used to calculated the redox 
potential in a poorly drained soil column collected from a flat landscape that has been in a 
traditional corn soybean crop rotation, and has less then 10% iron oxide containing clay.  
5
Chapter I: Speciation of Phytate is pH Dependent
Inositol phosphates are metabolically derived organic phosphates that increasingly 
appear to be an important sink and source of phosphate in the environment (Jayasundera, 
S et al. 2005), (Hansen et al. 2004), (Turner et al. 2001).   Inositol hexkisphosphates 
exhibit twelve acid protons in solution.  Acid dissociation constants have been published 
for myo-inositol hexkisphosphate or more commonly called phytic acid or phytate 
(Champagne, 1988).  A fractional speciation diagram was generated from this data 
(Figure 1).  The pH driven acid/base speciation changes of phytic acid is important to 
understanding its ability to complex metals in soil and aqueous ecosystems.  Metal-ligand 
interactions are known to change solubility and mobility in response to pH (Strumm and 
Morgan, 1996; Morel and Hering, 1993).  Phytic acid acting as ligand is likely 
participating in such reactions.  
6
Figure 1.  Speciation of myo-inositol hexakis dihydrogen phosphate (phytic acid) from 
acid dissociation constants (pKa). 
Myo-Inositol hexkis phosphate speciation

0=H
12
PA

4=H
8
PA
4-

5=H
7
PA
5-

6=H
6
PA
6-

7=H
5
PA
7-

8=H
4
PA
8-

9=H
3
PA
9-

10=H
2
PA
10-

11=HPA
11-

12=PA
12-
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
1357911 13
pH
S
p
e
c
i
e
s
 
f
r
a
c
t
i
o
n
a0=H12PA
a1=H11PA1-
a2=H10PA2-
a3=H9PA3-
a4=H8PA4-
a5=H7PA5-
a6=H6PA6-
a7=H5PA7-
a8=H4PA8-
a9=H3PA9-
a10=H2PA1
0-
a11=HPA11-
a12=PA12-
Methods
An excel spread sheet was used to calculate and graph the pH driven fractional
species change of phytic acid (Strumm and Morgan, 1996; Morrel and Hering, 1993). 
The calculation was preformed at one unit intervals from  pH 1 to 14.  Each species (
) 
fraction was generated by the disassociation of a sequentially lost proton.  The acid 
dissociation constants K govern the pH of the proton loss.  The number designation 
associated with each fraction (
) represents the protons removed from the molecule and 
identifies each fraction.  
7


0
 +  

1
 + 

2
 + 

3
 + 

4
 + 

5
 + 

6
 + 

7
 + 

8
  + 

9
 + 

10 
+ 

11
 + 

12
 = 1


0
 = fraction of species in the form H
12
A


1
 = fraction of species in the form H
11
A
-
.
.

j = fraction of species in the form HjA
The general form of speciation for a polyprotic acid H
n
A is


0
   = [H
+
]
n
D


1
 = K1[H
+
]
n-1
D
.
.

j = K1K2?..Kj[H
+
]
n-j
D
where D = [H
+
]
n
 + K1[H
+
]
n-1
 + K1K2[H
+
]
n-2
 + ??.+ K1K2K3.......Kn
Results and Discussion
Results demonstrate that for any environmentally relevant pH, at least one fifth of 
phytate molecules will not have the same charge as the most abundant phytate species.  
For example pH 6, the major species of phytate (H
4
PA
-6
) has a net charge of ?6, but 
(H
3
PA
-5
) which has a ?5 charge and (H
5
PA
-7
) which has a ?7 charge will also be present.  
The average charge from both the 20% (H
3
PA
-5
) and the 20% (H
5
PA
-7
) remains  ?6, but 
at the molecular level, 40% of phytate will have the physical chemical properties of either 
(H
3
PA
-5
) or (H
5
PA
-7
), and not of (H
4
PA
-6
).
8
At pH 7 phosphate buffers are nearly an equimolar ratio of monobasic (H
2
PO
4
-1
) 
and dibasic (HPO
4
-2
) phosphate.  The phosphate speciation does not change between pH 
5 and 7: only the relative abundance between these two species changes.  For similar 
reasons, phytate speciation changes with pH predictably for the each of the twelve acid 
dissociation constants (pK
a
s) of phytate.  Between pH 5 and 7 four species of phytate 
account for nearly all the phytate present. However, unlike phosphate, the relative 
amounts of all four species, not just two, change systematically as one alters pH.
The co-existence of multiply charged species at any ecologically relevant pH is an 
essential part in understanding phytate ligand solubility and organic P mineralization. The 
strength and affinity of any cation associated with a phytate species can be expected to 
change proportionately to the unit anion charge.  Binding will not necessarily prefer the 
most abundant phytate species and multiple species of phytate can simultaneously 
support multiple cationic ligands.  The multiply charged species of phytate present at any 
one pH often precludes stoichiometric complexation of phytate with single metal cations. 
At pH 6 (H
4
PA
-6
) can form a neutral complex with two Al
+3 
cations, but any Al
+3
complexes with (H
3
PA
-5
) or (H
5
PA
-7
) will simultaneously be charged.   
The pH dependence of phytate associations with trace metals, sesquioxides, 
colloidal clays, and fluvic and humic material has been reported (Stewart et. al. 1987).  
However, the composition of such phytate-ligand complexes will always be 
heterogeneous. Competitive binding will always occur among the multiple phytate 
species for any particular ligand present.  A ligand can more preferentially bind to less 
abundant species of phytate with a higher net charge than to a more abundant phytate 
species with a lower net charge.  Elucidation of the mechanisms and hierarchy of 
9
complexation requires identification of the distribution of charge on individual phytate 
sites with changes in speciation. 
Enzymatic dephosphorylation occurs via two currently recognized forms of 
phytase, 3-phytase (E.C.3.1.3.8), which is microbial in origin and is most active at pH 2.5 
and 5.5 and 6-phytase (E.C. 3.1.3.26), which is produced by some plants and is most 
active at pH near 5 (Pallauf, 1997). Optimal enzymatic activity could be due to pH 
dependent properties of the enzyme.  A simpler explanation is that phytase-3 or -6 binds 
preferentially to specifically charged sites on the phytate molecule and that the charges 
on the phytate are strongly pH dependent.  From Figure 1, H
8
PA
-4
 and H
9
PA
-5
 are the 
most abundant forms at pH 2.5; H
4
PA
-7
 is the most abundant form at pH 5 to 5.5.  The 
H
4
PA
-7
 species must have at least one phosphorus site on the molecule with a ?2 charge 
and the P site with the ?2 charge could be the first site of enzymatic dephosphorylation. 
Reactions at pH 2.5 may be more complex, but any molecular mechanism to explain why 
3-phytase is different from 6-phytase needs to adequately address phytate speciation.
Equimolar ratios of transition metal-phytate complexes have been shown to 
inhibit enzymatic dephosphorylation rates (Dao, 2003).  The phytate complexation and 
phytase enzyme activity occur concurrently and correspondingly the activation or 
deactivation that can occur from mineral complexation.  At equimolar ratios of a 
transition metal and phytate, cation binding to the ?2 anionic site would makes that site 
less available for enzymatic activity.  
Speciation is innately part of the fate and transport of phytate.  Computer models 
that predict the fate of organic phosphorus in soils are seriously incomplete if only one 
form of organic phytate is assumed to be present.  Between pH 6 and 7.5, five species of 
10
phytate are present and as much as 60% of the phytate will not have the same molecular 
charge as the predominant molecular species.  Analyses of phytate in soil systems 
designed to extract specific phytate species will measure only a fraction of the phytate 
species actually present in soil.  Moreover, because each phytate molecule contains six 
phosphorus atoms, an error of about 8% in quantifying the amount of soluble phytate 
extracted would equal a 50% error in the measurement in the contribution of organic 
phosphorus from phytate to the total phosphate pool.  Un-extracted phytate species can be 
a significant reservoir that is routinely undefined or misidentified in analysis of soil 
phosphorus.  Accurate environmental mass balance and kinetic calculations for organic 
and inorganic phosphorus in soils is incomplete unless speciation of phytate is explicitly 
part of the accounting.
11
Chapter II: Kinetic and Equilibrium Constants of Phytic Acid, and Ferric and Ferrous 
Phytate Complexes derived from Nuclear Magnetic Resonance Spectroscopy
The fate and transport of phosphorus (P) is an emergent problem affecting 
environmental resources.  Long time land application of P enriched manure has been 
implicated in the saturation of available P binding sites in many terrestrial, wetland and 
sediment systems.  Transport of soluble- or particle- associated P by overland flow and 
possibly by subsurface leaching has increased eutrophication in waterways on the east 
coast of the United States, Europe and increasingly in Asia (Sims et al.1998).  
The P cycle is not completely elucidated and resists conforming to reliable mass 
balance calculations.  Inclusion of organic forms of P in mass balance calculations may 
yield more satisfactory results.  The most prevalent form of organic P is Myo-inositol-1, 
2, 3, 4, 5, 6-hexakis dihydrogen phosphate or more commonly phytic acid (PA) (Bar-
Yosef et. al.1993).  Phytate is the non-protonated anion.  Phytic acid contains six mono-
phosphate groups on a six carbon ring (Figure 2).  
12
Figure 2. Structure of Myo-inositol-1,2,3,4,5,6-hexakis dihydrogen  phosphate or more 
commonly phytic acid (C
6
H
18
P
6
O
24
) 
The environmental impact of the organic pool is biologically driven by uptake of soluble 
phosphate and repackaging as an organic phosphate. Phytic acid and its pentaphosphate 
analog represent 60% of the organic phosphate in soil (Bar-Yosef et al. 1993).  Diesters 
such as nucleotides and phospholipids occur at much lower concentrations of 5% and 
<1% respectively.  The diester compounds are derived from decomposing plant and 
animal material (Bar-Yosef et al.1993).  Diesters are highly labile and rapidly recycled by 
biota.  The monoester phytic acid has been identified as a phosphate storage molecule 
           O
HO     P== O                           
        HO
OH 
 
O == P OH
O
H
H
H
H
HH
           O
HO     P== O                           
        HO
OH 
 
O == P OH
O
OH 
 
O == P OH
O
OH 
 
O == P OH
O
Non Acidic Protons
Acidic Protons
13
involved in the germination of seedlings (Brinch-Pedersen et al. 2002).  Monoesters such 
as phytic acid are less likely to be bio-available than diesters because of their high surface 
to charge ratio.  Aluminum and ferric complexes of phytic acid have been found to inhibit
enzymatic dephosphorolation, indicating a potential to persist in soil systems (Dao 2003).  
Phosphorus levels in soil are dependent on the mineral composition of the soil, the 
anthropological inputs of fertilizer, decomposing detritus and outputs of crop removal or 
erosion.  Concentrations of phosphorus in soil range 300 to 4700 mg Kg
-1
.  The organic 
fraction of the total phosphate concentration can vary from 20 to 80% in surface soil 
horizons (Brady and Weil 2000).   Iron oxide and aluminum oxides form strong 
recalcitrant complexes with phosphates that in the case of iron are susceptible to 
oxidation reduction reactions as well as pH dependent equilibria (Stewart and Tiessen 
1987).   
Available iron and aluminum oxide reaction sites in soil systems may be saturated 
in some instances especially in non-tropical soils that have moderate levels of oxides 
(Brady and Weil 2002; Brinch-Pedersen et al. 2002).  Historical increases in agricultural 
production were fueled by increases in fertilization rates of phosphates as well as other 
nutrients.  Transport of phosphate from upland terrestrial to aquatic systems may be 
related to the capacity of a soil system to complex phosphate with iron and aluminum 
oxides.  Equilibrium constants for inorganic phosphates are well characterized.  
Solubilization of iron phosphate complexes is known to respond to changes in the 
oxidation reduction status.  Equilibrium, kinetic and solubility constants as well as 
oxidation reduction potentials for many organic phosphates such as phytic acid and its 
complexes are unavailable in the literature.
14
Phytic acid can be enzymatically dephosphorolated by phytases from plant, 
microbial and animal sources.  Aspergillus ficcum is a soil microbial component that 
produces 3-phytase (E.C. 3.1.3.8).  This phytase acts on the C
3
 phosphate group 
preferentially but eventually dephosphorolates all six phosphates on the PA molecule 
(Pallauf and Rimbach 1997).  
Phytic acid and phytases are supplied naturally and also anthropologically, 
entering terrestrial systems in manure and as plant decomposition by-products.  Phytic 
acid is found at high concentration in small grain producing plants.  As much as 70% of 
dry weight mater in germinating seedlings is phytic acid (Brinch-Pedersen et al. 2002).  
The high content of phosphate per molecule of phytic acid makes it a logical choice for a 
livestock phosphate supplement.  Where phytases are not produced by the animal, they 
may be supplied in the feed as for poultry, or the phytic acid molecule can be 
enzymatically dephosphorolated before feeding, as in swine livestock production 
(Brinch-Pedersen et al. 2002).  Phytic acid has been found in bovine, swine and poultry 
manure (Brinch-Pedersen et al. 2002).  It is clear that the addition of phosphate to the diet 
increases growth rate but the efficiency of digestion may not be improved and higher 
levels of phosphate may occur in manures of animals fed on a phytic acid, phytase 
supplement.  The fractionation of the inorganic and organic pools of phosphate in 
manure, soil and water is an area that should be examined (Sims, 1994; Brinch-Pedersen 
et al. 2002).  
Iron is a common component in many soils on the east coast of the United States, 
making it a potential metal -phytic acid complex of interest.   Determination of kinetic, 
15
equilibrium and solubility constants for complexes of phytic acid will contribute to the 
understanding of the fate and transport of phytic acid and its role in the phosphorus cycle.   
The objective was to use proton nuclear magnetic resonance to derive kinetic (k) 
and equilibrium constants (K
d
), (K
f
) for ferric and ferrous phytate.  In addition, the 
relative magnitude of the kinetic constants was supported by the concentration of 
phosphate produced by enzymatic dephosphorolation of phytic acid and ferric and ferrous 
phytate.  
Materials and Methods 
Nuclear Magnetic Resonance
Phytic acid in an aqueous solution of 50 % D
2
O was pH adjusted to 4.0, 6.0 and 
8.0 and monitored on a 300 MHz proton nuclear magnetic resonance spectroscopy (H-
NMR).  Complexes of ferric and ferrous iron where then monitored at pH 4.5. The 
ferrous complex was protected from oxidation by nitrogen gas.  The NMR tube was 
permanently sealed by melting the open end of the tube with a blow torch. 
Kinetic and Equilibrium Calculations from NMR Spectra 
Kinetic constants (k) for hydrogen, ferric and ferrous complexes of phytate were 
derived by monitoring the spectral shift of each complex with proton nuclear magnetic 
resonance spectroscopy (H-NMR).  The twelve protons associated with the six phosphate 
groups have acid dissociation constants that participate in trace metal chelation but do not 
produce the H-NMR spectra being monitored.  The six non-acidic protons on the carbon 
ring respond to the trace metal chelated with the phytate molecule; producing a spectral 
shift that is a direct measurement of the kinetic rate constant for the metal-phytate 
complex..
16
The spectral shifts were measured in ppm hertz (One hertz equals a reciprocal 
second).  The kinetic formation constant was measured as the change in location of the 
highest peak on the x axis x  10
-6
 s
-1
.
k
                         nCation + Anion   =    Cation-Anion Complex                    [1]
The cation was hydrogen, ferric or ferrous iron.  The anion was phytate.  The 
thermodynamic constants (K
f
) and (K
d
) were derived from the ratios of the hydrogen and 
metal kinetic constants when the activities of the reactants are in equilibrium (Levitt, 
2003).  
K
f
 = k
metal
/k
hydrogen
[2] 
K
d
 = k
hydrogen
/k
metal
   [3]
Enzymatic Analysis
Ferric and ferrous complexes of phytic acid were incubated at pH 4.5 and 24
o
C 
with 0.03 units/ml of Aspergillus ficcum (E.C.3.1.3.8) purchased from Sigma.  Phytic 
acid and metal-phytate complexes were prepared in mM ratios of PA to Iron at 
concentrations ratios of 1:0, 1:0.6, 1:0.3 and 1:0.1.  Incubation occurred over a time 
course of 15, 30, 60, 90, 1080, 1440 and 2880 minutes.    The highest concentration 
treatment of ferric and ferrous phytate was governed by the solubility of the ferric phytate 
treatment.  The 1mM PA and 0.6mM ferric iron were allowed to equilibrate at pH 4.5 
overnight to determine visible precipitate.  The solutions used for the analysis were 
prepared just prior to the addition of the enzyme solution.
The concentration ratios were incubated with enzyme present and enzyme absent 
representing samples and controls respectively.  The enzyme was denatured by boiling 
17
for 15 minutes, acidified by adding of 200ul of 1M hydrochloric acid to prevent 
precipitation of ferric phosphate immediately after boiling and frozen until analysis.  
Liberated phosphate ion was analyzed colormetrically by an ascorbic acid molbdate 
reaction (Murphy and Riley, 1962).  Controls were subtracted from matching samples.  
The ferrous complexes were protected from oxidation by a blanket of nitrogen and sealed 
in polyethylene tubes.  Controls and sample were prepared and analyzed in triplicate.   
Statistical Analysis
The program SAS 5.1 (SAS Institute 1989) was used to test for statistical 
differences in phosphate concentration across treatments for the reaction times of 1080, 
1440 and 2880 minutes.  Analysis of covariance (ANCOVA) was used to assess 
differences through time and among treatments.  The reaction time 2880 minutes was 
chosen to calculate the percent recovery of the 1mM phytic acid treatment.  All analysis 
were considered statistically significant at p<0.05.  The null hypothesis stated no 
difference between the concentrations of phosphate recovered from each treatment.  The 
alternative hypothesis stated that one or more treatments have significantly different 
concentration of phosphate recovered from the enzymatic dephosphoralation.  A pair 
wise analysis of variance was preformed for each possible pair of treatments.  For k 
number of treatments k (k-1)/2 different treatments were compared.  The means of 
treatments with significant variance were ranked in order of magnitude and a multiple 
comparison test was used to determine if a difference existed between means.  A 
calculated q value was generated according to equation [4].
q = mean of treatment k1 ? mean of treatment k2 [4]
standard error
18
where standard error = square root of error mean square from the analysis of 
variance of the means divided by the number of samples in the treatments. 
The calculated q was compared to a tabulated q.  When the calculated q was 
found to be greater then tabulated q the null hypothesis was rejected and the treatments 
were found to be different.  The tabulated q was based on possibility of falsely rejecting 
at least one null hypothesis, the error degrees of freedom from the analysis of variance 
and the total number of means being tested.
Results
Constants derived from Nuclear Magnetic Resonance Spectra
Changes in pH did not affect the H-NMR spectra of phytic acid making it an 
appropriate method for monitoring changes in kinetic rate constants (Figure 3).  Spectral 
shifts were attributed to the cation associated with the phytate molecule.  The kinetic rate 
constant for phytic acid, ferric phytate and ferrous phytate were 4.69, 4.21 and 3.95 x 10
-6
 
s
-1
 respectively (Figure 4).  The experimental equilibrium rate constant for the 
dissociation of ferric phytate (K
d
) was 1.114 and the equilibrium dissociation constant 
(K
d
) for ferrous phytate was equal to 1.186.  The experimental formation constants (K
f
) 
are 0.899 and 0.843 for ferric and ferrous phytate respectively.  
19
Figure 3.  Proton Nuclear Magnetic Resonance (1H NMR) indicates no  peak shift due to 
pH in aqueous samples of phytic acid making NMR an appropriate tool for monitoring 
phytic acid metal binding constants.  
pH 4
pH 6
pH 8
20
Figure 4.  Proton NMR Spectra of Ferric and Ferrous Iron Complexes of Phytic Acid at 
pH 4.5 NMR spectra of phytic acid and phytic acid complexes of ferric and ferrous iron 
show shifts in spectral peak maxima.  Observing the largest peak of each spectrum: 
changes in ppm, when converted to s
-1
 yield the kinetic rate constant for the formation of 
the PA-Metal complex. The phytic acid spectra show the kinetic acid disassociation 
constant.  Phytic acid = 4.69 x 10
6
 s
-1
, the complex of ferric phytate = 4.21 x 10 
6
 s
-1
 and 
the ferrous phytate = 3.95 x 10
6
s
-1
.
Ferrous phytate
Ferric phytate
21
Enzymatic Dephosphorolation
Significant differences existed among all of the treatments with the except ion of 
ferric phytate with a treatment concentration 0.6mM and ferrous phytate with a treatment 
concentration of 0.3mM (Table 1: ANCOVA F=84.16; P<0.0001).  The phosphate model 
was significant (ANCOVA r
2
=0.989; F=343.63; P<0.0001).  Treatment and Time
covariant with Treatment are significant (ANCOVA F =84.16 and 12.47 respectively; 
P<0.0001).  The independent time variable was not significant (ANCOVA F=3.45; 
P=0.0691 ).  Table 1 summarizes the average (n=3) phosphate (ug/ml) liberated by the 
enzyme phytase over the series of incubation times and gives the percent recoveries for 
time=2880minutes.   Phytic acid with a concentration of 1mM or 57ug/ml was 98 % 
dephosphoralated at the time 2880 minutes.  The non enzyme controls were not reported 
in Table 1.  The average and standard deviation of the control data points was 3 + 1 
(N=147).  The percent recovery of phosphate ion from the enzymatic dephosphoralation
of phytic acid must account for the 6mM of phosphate ion per 1mM of phytic acid.  
The molecular weight of phosphate ion is 95 g/mole.  The expected concentration of 
phosphate ion from a 1mM solution of phytic acid was calculated as in equation [5].         
(0.0006 mol/L PO
4
2-
) x (95 g/mol) x (1L/1000 ml) x (1*10
6
 ug/g) = 57ug/ml PO
4
2-
    [5]
22
Table 1.  Seven treatments were prepared each contained 1mM of phytic acid.  Three of 
the six treatments contained ferrous phytate in the mM concentrations listed.  The 
remaining three treatments contained ferric phytate in the concentrations listed.  
Recoveries of enzymatically dephosphoralated phosphate ion are in ug/ml.  The tukey 
group letters denote statistical difference.  Treatments with the same letter are not 
statistically different. 
Treatment Concentration (mM)
in each Treatment
Concentration (ug/ml)
of phosphate recovered
% HPO
2- 
Recovered at T=2880
Tukey
Groups
Phytic acid 1.00 56.0 + 0.5 98 A
Ferric Phytate 0.1 38.6 + 2 68 B
Ferrous Phytate 0.1 34.6 + 1 61 C
Ferric Phytate 0.3 30.5 + 2 54 D
Ferrous Phytate 0.3 19.1 + 0.5 33 E
Ferric Phytate 0.6 17.2 + 3 30 E
Ferrous Phytate 0.6 9.7 + 1 17 F
Discussion
Ferric and ferrous iron form complexes with phytic acid that can persist in 
solution and resist dephosphoralation by the enzyme phytase.  The experimental kinetic 
constants derived from proton nuclear magnetic resonance indicated that ferrous phytate 
forms faster and dissociates at a slower rate then ferric phytate although they are of the 
same order of magnitude. The H-NMR derived findings are supported by the overall 
enzymatic dephosphoralation recoveries of phosphate over a 2-day period.  The 
phosphate recovered from the enzymatic dephosphoralation of ferrous phytate was 
23
significantly less then the phosphate recovered from ferric phytate and phytic acid alone.  
The phosphate dephosphoralated from ferric phytate was also significantly less then the 
phosphate dephosphoralated from uncomplexed phytic acid.  
Ferrous phytate is soluble at higher pH then ferric phytate but at atmospheric 
levels of oxygen is rapidly converted to ferric phytate and precipitated out of solution.  In 
anoxic ground water, ferrous phytate has the potential to resist microbial decomposition 
from the enzyme phytase.  This ability to persist may enable ferrous phytate to be 
transported by subsurface leaching.  Agricultural areas that are prone to saturated soil 
conditions on a seasonal basis or are continually saturated and adjacent to agricultural 
areas receiving manure fertilizers have the potential to export phosphate as ferrous 
phytate.  
Young and Ross, 2001 found that 13 of 14 seasonally flooded soils from the 
Champlain Valley in New York increased pore water phosphate concentrations over a 60 
to 90 day period, additionally five of the soils exhibited increased ferrous iron 
concentration concurrently with phosphate pore water increases.  The soils that exhibited 
increased ferrous iron and phosphate concentrations in pore water exhibited decreased 
flood water phosphate concentration indicating retention of phosphate in the pore water 
possibly in association with ferrous iron. In soils with no ferrous iron present the pore 
water to flood water phosphate concentration ratios ranged from 1.0 to 3.3 suggesting 
equilibrium between flood water and pore water or retention of phosphate in pore water.  
Young and Ross hypothesize that phosphate solubility and transport are mediated by the 
available phosphate status and seasonal anoxia of saturated soils.  The ratio of pore water 
24
to flood water phosphate concentration implicates subsurface leaching as a likely 
transport mechanism in saturated soils.  
Butler and Coale, 2005 investigated four coastal plains soils in Maryland and 
concluded that phosphorus losses to surface waters by overland flow processes was more 
of a concern then subsurface leaching of phosphorus.  The fraction of the phosphorus 
pool investigated by Butler and Coale were water extractable phosphorus and soil test 
phosphorus.  Water extractable phosphorus is a measure of phosphate immediately 
available to plants and soil test phosphorus is a measure of plant available phosphorus 
over the growing season.  Phytic acid is unlikely to fall into either of those fractions 
because of its potential to persist in soil systems and resist dephosphoralation.  The six 
mono-phosphate groups associated with phytic acid would not be evident in either 
fraction because phosphate derived from phytic acid requires enzymatic 
dephosphoralation.  
The conversion from ferric iron to ferrous iron is mediated by oxidation reduction 
(redox) reactions.  Phosphorus has a valence of +5 and does not respond directly to redox 
processes, but iron cations associated with a phytate molecule will respond to changes in 
redox potential. Phytic acid acting as a ligand can change the potential of the redox 
process, making investigation of the iron phytate redox couple an area of interest for 
further research.   Redox processes in many soil systems are temporal and known to 
reflect seasonal fluctuations of the water table.  Landscapes that can support reducing 
soils are also highly variable spatially (Richardson et al, 2001).  Export of phosphate as 
ferrous phytate and storage of phosphate as ferric phosphate is possible and an area of 
25
interest in the phosphorus cycle.   Investigation of iron complexes in soil systems should 
incorporate temporal and spatial components. 
Celi et al, 1999 investigated the adsorption of phytic acid and phosphate ion on 
common soil clays goethite, illite and kaolinite usi ng fourier-transform infrared (FT-IR) 
spectroscopy found that the mechanism for absorption was the phosphate groups on the 
phytic acid molecule.  They inferred that phosphate groups on phytic acid form 
complexes with surface Fe-OH groups on the clay in an analogous manner to phosphate 
ion.  Goethite had the greatest capacity to complex phytic acid with four of the six 
phosphate groups postulated to be participating in the complexation reaction.  Illite and 
kaolinite although less effective then goethite in complexing phytic acid were found to be 
more effective then phosphate ion.  The illite and kaolinite had two ferric hydroxyl sites 
on the clay complexed by the phytic acid.  The results suggest displacement of phosphate 
ion by phytic acid in soil systems containing goethite, illite and kaolinite clays due to 
lowering of the bond energy of P=O group and the stabilization of multiple P-O bonds 
(Celi et al, 1999).   The displacement of phosphate ion by organic phosphates has been 
reported by Anderson, 1980 and Cosgrove, 1977. The uncomplexed phosphate groups of 
the phytic acid clay complexes negatively change the surface of the clay and effectively 
decreased the size of the clay aggregates leading to greater overall clay surface area for 
absorption of phytic acid, incomplete mineralization, accumulation in soils and a negative 
impact of phosphorus bioavailability (Celi et al, 1999; Stewart and Tiessen, 1987).  
Conclusion
Phosphorus fate and transport is an emergent problem impacting sensitive aquatic 
ecosystems.  Long time land application of phosphate enriched manure has been 
26
implicated in the saturation of available phosphate binding sites in many terrestrial, 
wetland and sediment systems.  Phosphate binding sites in many soils are believed to be 
clays such as goethite, illite and kaolinite that contain exposed oxides on their surface 
layer.  Transport of organic and inorganic forms of phosphate from terrestrial to aquatic 
systems is not completely understood but in the case of oxide containing clays must 
involve acid base or oxidation reduction reactions.  Phytic acid has a large charge to mass 
ratio and an ability to chelate ferrous and ferric iron in solution.  Iron is ubiquitous in 
many soils that receive phosphorus rich manure inputs making iron phytic acid
complexes metal ligand reactions likely to occur in soil systems that contain iron oxides 
such as goethite.  In solution the ferrous phytic acid complex exhibits a higher 
equilibrium constant and is soluble at relevant soil pH implicating subsurface leaching of 
ferrous phytic acid complexes as a likely phosphate transport mechanism.  Ferric phytate 
is much less soluble than ferrous phytate at environmentally relevant pH and may be an 
important binding site for phytic acid in iron containing oxidized soil systems.  Soil 
systems prone to seasonal or periodic soil pore water anoxia may support cycles of 
fixation and mobility of iron associated phytic acid complexes.  
Inorganic phosphate is known to be to be particulate and sediment attached.  It is 
easily transported with sediment in above ground overland flow.  Ferric oxides form 
strong recalcitrant complexes with phosphates. Equilibrium and kinetic constants for 
inorganic ferric and ferrous phosphate complexes are well characterized. Complexes of 
ferric phosphates are susceptible to oxidation-reduction reactions as well as pH 
dependent equilibrium.  Ferric and ferrous complexes of organic phosphates are not 
characterized.  Determination of equilibrium constants of ferric and ferrous complexes of 
27
phytic acid will contribute to more accurate mass balance calculations in soils with iron 
content.  Results suggest subsurface transport of phosphate, as a ferrous phytic acid 
complex from terrestrial systems to eutrophication sensitive waterways  is a possible and 
previously neglected pool of phosphate.  Inclusion of organic forms of phosphorus in the 
phosphorus budget may lead to a more reliable mass balance calculation and a better 
understanding of the phosphorus cycle.  A thorough understanding of the phosphorus 
cycle is an essential first step toward limiting phosphorus export to aqueous ecosystems.     
28
Appendix I: Potentiometric measurement of ferric and ferrous species in soil 
columns containing Elkton soil series, Queen Anne County, 
Maryland
Abstract for Appendix I
Soil columns from Queen Anne County, MD were collected in order to have an 
applied test for proton nuclear magnetic resonance spectroscopy derived formation and 
dissociation constants of ferric and ferrous complexes of phytic acid.  The concentrations 
of ferrous and ferric iron were measured potentiometrically at three levels within the 
column and in the column effluent with platinum working electrodes and a silver/silver 
chloride reference electrode in order to determine the oxidation reduction potential of 
goethite and ferrous iron redox couple within the column and the export of ferrous iron 
from the column.   
Geographic areas that are likely support the export of phosphorus as ferrous 
phytate must be prone to development of anoxic soil pore water, contain iron oxide clays 
such as goethite, and have poor to moderate permeability and low slope.  Correlation of 
landscape features or soil taxonomy to ferrous iron concentration in soil could be an 
indicator of phosphorus export as ferrous phytate by subsurface leaching.  
Introduction
Ferrous phytate is a soluble complex at environmentally relevant pH and has been 
shown previously to form readily and resist microbial degradation.  Ferric phytate is 
much less soluble but also resists microbial degradation from the soil microbe Aspergillus 
ficcum, a common soil constituent.  Traditionally inorganic phosphorus as phosphate is 
thought to be transported in association with sediment in overland flow processes (Sims 
et al, 1998).  The ferric ferrous redox couple is a control of phosphate ion solubility in 
29
areas where iron is found in soil.  Ferric phosphate is not highly soluble while ferrous 
phosphate disassociates releasing phosphate ion.    Movement of reduced iron is readily 
observable in many soil systems as iron concentrations and depletions (Richardson et al., 
2002).  It could be expected that organic phosphates would behave in an analogous 
manner to inorganic phosphates but we have found that not to be the case based on 
equilibrium constants derived from nuclear magnetic resonance spectroscopy.  
Organic phosphates have been thought to be highly labile and converted quickly 
to inorganic phosphates due to efficient dephosphoralation and recycling by the microbial 
community (Graf, 1986).  We have shown previously that ferric and ferrous phytate resist 
microbial degradation.  The stability and solubility of ferrous phytate implicate 
phosphorus transport by subsurface leeching of the organic monophosphate complex of 
reduced iron, ferrous phytate.   Ferric phytate also resists microbial dephosphoralation; 
but with much lower solubility then ferrous phytate.  It can possibly sequester phosphate 
as the oxidized ferric phytate.
Eutrophication has become a major problem in many east coast watersheds 
including the Delmarva Peninsula.  A desire to control the outcomes of eutrophication, 
which by definition is an excess of nitrogen, phosphorus or both in surface water leading 
to excessive plant growth, oxygen depletion and in extreme cases fish kills is of intrinsic 
value as well as being of practical importance in maintaining clear and navigateable 
waterways for the traffic of goods, recreational uses such as boating and fishing and 
maintaining human and animal health (Hamilton et al., 1993).
Several naturally occurring factors such as the geology, topography, climate and 
hydrology in combination with anthropological activities such as grain crop production, 
30
concentrated livestock production and urbanization lead to situations where 
eutrophication can occur.  The Delmarva Peninsula is an example of such a situation.  
Comprised of the state of Delaware and the coastal portions of Maryland and Virginia 
bounded by the Chesapeake Bay it is part of the North American geological coastal plain.  
The Delmarva this is described as unconsolidated sediments composed of varying 
proportions of clay, sand and gravel (Schmidt, 1993).  These sediments have not yet been 
compressed into solid sedimentary rock.  This type of geology generally has high rates of 
infiltration and when combined with the low relief topography implicates ground water 
recharge as the primary hydrologic process in the undisturbed ecosystem.   Within the 
ecosystem there are significant areas that do not have high rates of infiltration.  Areas in 
agricultural production have used extensive ditching to remove water expeditiously thus 
expanding areas available for crop production (Schmidt, 1993).   
The dominant soil order is Ultisol, which is a low nutrient soil that when used for 
crop production requires inputs of nitrogen, phosphorus and potassium in order support 
optimal plant growth.  Alfisols are also found and are a high nutrient soils but they are a 
smaller representative proportion and frequently not available for cultivation due to 
location in the landscape and the position of the water table. Those parcels of land 
completely unsuited for agricultural uses are in many cases left to native vegetation, 
which was historically mixed hard wood forest or tidal marsh.  The juxtaposition of well 
drained cultivated land, networks of drainage ditches close to sensitive waterways and an 
adequate supply of precipitation leads to the perfect scenario for eutrophication. 
(Hamilton et al, 1993)  
31
We hypothesize that in areas capable of supporting reducing ground water and 
containing iron sesquioxides there is a potential for export of phosphate as ferrous 
phytate by subsurface leeching.  A potentiostatic three electrode system, two platinum 
electrodes and a saturated Ag/AgCl reference electrode was used to measure the ferric 
and ferrous iron concentration within a soil column containing a poorly drained soil, 
USDA Elkton from Queen Anne County, Maryland.  The effluent from the column was 
monitored for ferric and ferrous iron concentration by potentiostat and a standard curve 
measuring concentration of iron as a function of current.  The Nernst equation will be 
used to calculate the cell potential according to equations [6] and [7] within the soil 
column and in the effluent.  
E
cell
  =  E
(Fe3+, Fe2+)
- E
(Ag/AgCl)
[6] 
 E
(Fe3+, Fe2+)
  =  E
o
  +  2.3RT  log[Fe
3+
]                     [7]
nF       [Fe
2+
]
The oxidation reduction potential will be calculated according to equations [8]
and [9].  
Fe(OH)
3(s)  
+  3H
+
  +  e
-
  =   Fe
2+
  +  3H
2
O log K = 16        [8]
E
H(ox-red)
  =  E
o
Fe(OH)3-Fe2+
 +  2.3RT  log  [H
+
]
3
[9]
nF         [Fe
2+
]
where R = Ideal gas constant in 0.082057 liter atmdeg
-1
mol
-1
, T = temperature (K), F = 
Faraday Constant (charge of 1 mole of electrons)in 96,485 C mol
-1
 and n = the number of 
electrons in the system.
Calculations for pE of goethite/ferrous couple and the partial pressure of oxygen pO2 are 
represented in equations [10], [11], [12] ,[13] and [14]
pE = pEo
Fe(OH)3
-
Fe2+
 + log {H
+
}
3
[10]
{Fe
2+
}
32
pE = 16 - 3pH + pFe
2+
[11]
O
2
(g) + 4 H
+
 + 4e-  =  2H
2
O [12]
pE = pEo + ? log pO
2
*{H
+
} [13]
log pO2 = 4(pE ? pEo + pH ) [14]
where pEo
Fe(OH)3-FE2+
 = 16, pEo
O2(g)
 = 20.8
Ferric and ferrous phytate was be monitored in the effluent by proton nuclear 
magnetic resonance spectroscopy. 
Materials and Methods
In order to test this hypothesis, 3 soil columns were collected from Wye Island, in 
Queen Anne County, Maryland.  Platinum electrodes were constructed, installed 
horizontally in each column at 5, 15 and 30 cm and monitored potetiometrically twice a 
day for 3 days.  The platinum electrodes were replicated twice at the 5 cm level and 4 
times at the 15 and 30 cm levels.  The column effluent was monitored poltentiometrically 
at four hour intervals for a four day period.  Ascorbic acid and peroxide were used to 
induce reducing and oxidizing conditions within the column.  Aliquots containing 0.4g of 
phytic acid in 100 ml of water were added to the column at two intervals on day 2 and 
day 3.  Three hundred ml of 0.1M ascorbic acid was added to water saturated columns on 
day 1.  One hundred ml of 3% solution of hydrogen peroxide was added on day 4. 
33
Platinum Electrode Construction
Platinum electrodes were constructed by cutting 12-gauge FT-1 rated solid copper 
wire insulated with gas and oil resistant 600V T-90 nylon into 12 inch lengths.  The wire 
was cored with 1 mm drill bit to a depth of approximately 0.3mm with a lath.  Platinum 
wire with a diameter of 0.0385 inches, purchased from DFG Goldsmith Chemical and 
Metal Corporation, Evanston, Ill. was cut into 0.6 mm lengths.  The platinum was 
inserted into the cored copper wire and commercially available Benzomatic MAPP gas 
consisting of 44% methylacetylene- propadiene and 56% liquefied petroleum gas was 
used to sweat the union of copper and platinum and ensure contact.   Epoxy was used to 
cover the exposed copper wire from the platinum copper interface to where intact plastic 
coating covered the copper wire.  Polyolefin shrink tubing was used to cover the epoxy.  
A second coat of epoxy was applied to the open end of the shrink tubing adjacent to the 
platinum wire.  Applications of epoxy were allowed to cure for at least 24 hours.  The 
electrodes were cleaned with 0.1M HCl and calibrated using a potentiometer with a 
saturated Ag/AgCl reference electrode.
Soil Column Collection
Three 12 inch diameter, 40 cm length schedule 40 PVC pipe were driven into the 
ground with a sledge hammer and excavated.  The columns were sealed on each end with 
kitchen plastic wrap and a rubber band for transport.  The effluent end of the column was 
fitted with ? inch concentric polyethylene disks glued together.  One circle fit within the 
internal diameter of the PVC pipe and the other covered the outer diameter.  A ? inch 
hole was drilled through the center of both disks.  A ? inch polyethylene fitting was used 
to drain the effluent from the columns.  The polyethylene fitting and the concentric disks 
34
were sealed with silicon glue.    The platinum electrodes inserted into the columns were 
also sealed with silicon glue.  The columns were kept moist with water while in storage.  
Soil Selection
The United States Department of Agriculture, Natural Resource Conservation 
Service, and Soil Taxonomy classification system lists Elkton as a fine-silty, mixed mesic 
Typic Ochraquult.  It has been listed as benchmark soil in Maryland commonly found in 
Queen Anne County.  It has moderately slow permeability and poor drainage and a slope 
of 1%.  The iron content ranges from 7.9 to 9.4% as goethite.  Elkton has an aluminum 
sesquoxide concentration of 23% and a pH of 4.8 to a depth of 88 cm.  The site used to 
collect soil columns was in a corn soybean crop rotation and was within 400 yards of 
University of Maryland soil pit designated as Elkton.    
Potentiogram Analysis
An EG&G Princeton Applied Research Model 362 Scanning Potentiostat and an 
ASEA Brown Boveri Model SE790 plotter were used to generate potentiograms.  The 
voltage was programmed controlled and cycled from -0.2 to -1.2 V.  The current was full 
scale at 100uA.  Ferric chloride was used to prepare a linear calibration curve that 
measured iron concentration as a function of current.  A second curve was generated in 
0.1 M ascorbic acid in order to ensure no interference in the potentiometric measurements 
due to ascorbic acid iron ligand interactions.  The y-axis of the potentiogram curves were 
measured with a ruler in units of centimeters for changes from baseline and a conversion 
factor in Ampheres/cm was used to convert length to current.  The inflection point of the 
curve on the x-axis was measure in units of V/cm in order to identify the redox couple.  
35
Results 
Two of the three soil columns did not have sufficient flow rate to be useful.  The 
soil column used for the experiment had a flow rate of 4.0 + 0.7 ml/hr.  Effluent was 
collected every four hours for 60 hours.  The pH and the concentration ratio of the 
ferric/ferrous couple were calculated for each data point (Figure 5).   The experimental 
potential of the ferric/ferrous couple E
Fe3+,Fe2+
 as well as the redox potential E
H(ox-red)
from the column effluent samples is presented in (Table 2).  The data reflect the use of 
the Ag/AgCl reference electrode which has a calculated value of 0.5722 V when the 
ferric/ferrous redox couple is at equilibrium concentrations.  The standard redox potential 
for the ferric/ferrous couple is 0.771 V at equilibrium.  
The potential of the ferric/ferrous couple was monitored at 5, 15 and 30 cm four 
times over the course of 2 days (Figure 6).   A pH of 4.8 was used to calculate the 
standard potential within the column according to the Nerst equation for the redox couple 
goethite and ferrous ion equation [9]. 
36
Figure 5. The ratio of the concentration of ferric to ferrous species is a function of 
the concentration of protons.  
Table 2.  Soil Column effluent collected every four hours over a three day period
pH and Ferric/Ferrous Concentration ratio from Soil colunm Effluent 
0
1
2
3
4
5
6
7
04812 16 20 24 28 32 36 40 44 48 52 56 60
Time (Hr)
p
H
pH
[Fe3+]/[Fe2+]
37
Figure 6.  The oxidation reduction potential of the ferrous ferric couple at three 
levels within the Elkton Soil column over a period of four days
Ferric Ferrous
sample ID concentration (M) concentration (M)
E
Fe3+,Fe2+
E
H(ox-red) pE logpO2 pH
c1 2.50E-04 2.50E-04 0.5722 0.771 13.03245 -21.87018 2.3
c2 1.21E-03 1.21E-03 0.5722 0.771 13.03245 -20.67018 2.6
c3 9.22E-04 9.22E-04 0.5722 0.771 13.03245 -20.07018 2.75
c4 4.42E-04 4.42E-04 0.5722 0.771 13.03245 -19.59018 2.87
c5 1.54E-04 2.98E-04 0.5553 0.754 12.74654 -17.01385 3.8
c6 5.80E-05 2.02E-04 0.5402 0.739 12.49201 -14.75197 4.62
c7 5.80E-05 1.54E-04 0.5472 0.746 12.60952 -19.04193 3.43
c8 5.80E-05 1.06E-04 0.5567 0.756 12.77129 -18.31484 3.45
c9 5.80E-05 1.06E-04 0.5567 0.756 12.77129 -18.31484 3.45
c10 5.80E-05 1.30E-04 0.5515 0.750 12.68289 -12.74842 4.93
c11 1.06E-04 1.54E-04 0.5626 0.761 12.87068 -10.75728 5.24
c12 1.54E-04 2.02E-04 0.5652 0.764 12.91494 -10.62023 5.23
c13 1.96E-05 1.96E-05 0.5722 0.771 13.03245 -6.750183 6.08
c14 1.06E-04 2.02E-04 0.5557 0.754 12.75317 -13.78732 4.6
c15 1.06E-04 1.06E-04 0.5722 0.771 13.03245 -12.67018 4.6
c16 1.00E-05 8.20E-05 0.5183 0.717 12.12118 -17.51527 4.3
38
Potential of the Ferrous Ferric Couple at three levels within the 
Colunm
0.869
0.5720.572
1.168
0.763
0.572
1.176
0.746
0.572
0.000
0.398
0.471
0.000
0.200
0.400
0.600
0.800
1.000
1.200
1.400
5 15 30
Level (cm)
E
F
e
3
+
,
 
F
e
2
+
 
(
V
)
June14,05 2pm
June15,05 9:30am
June15,05 2pm
June16,05 10:00am
39
Figure 7.  Examples of potentiograms of column effluent using a Ag/AgCl 
standard electrode.  The redox potential of a hydrogen reference electrode is 0.771 V.  
The Ag/AgCl is 0.1988 V.  E
Fe3+,Fe2+
= 0.771 V ? 0.1988V =   0.572 V
The proton nuclear magnetic resonance spectrophotometer was not operational in 
the time frame of this experiment.  The samples will be saved, analyzed and presented at 
a later date.  
Discussion
Iron was exported from the Elkton soil column as the ferrous species (Figures 5
and 6).  At the level of 5 cm the redox couple is in equilibrium as exhibited in figure 6.  
The concentration of ferrous and ferric iron is unity and the potential is the standard 
potential 0.771 V minus the adjustment for the Ag/AgCl electrode 0.1988.  The potential 
Iron Export
-1.2 V
-0.2 V-0.572  V
-1.2 V -0.2 V
No iron 
40
of the ferric/ferrous couple should and does equal 0.5722 V when in equilibrium using a 
saturated Ag/AgCl standard electrode.  Ferrous ion is being exported with the exception 
of the sampling time June 16, 2005 at 10:00 am.  At this time there is a decrease in ferric 
iron when compared to ferrous iron or there is insufficient moisture within the column 
interrupting the circuit between the reference electrodes and the working electrodes.  The 
conversion from ferric to ferrous ion is occurring at the same rate at the three other 
sampling times at level 5 cm.  At level 15 cm, the sampling times of June 14 and 15 at 
2pm and 9:30 am respectively show the system in equilibrium (Figure 6).  At level 15 cm 
and the finial two sampling times June 15 and June16 at 2pm and 10:00am the system is 
no longer in equilibrium as the concentration of ferrous iron is decreasing on June 15, 
2005 at 2:00 pm and increasing on June 16, 2005 at 10:00 am.  Ferric iron is being 
depleted and exported as the reduced ferrous ion from the higher levels of the column to 
the lower levels.  The soil column level 30 cm may have been anoxic prior to the 
introduction of the ascorbic acid.  The first two sampling times indicate ferric iron in 
excess of ferrous iron and iron is observable in the effluent from samples corresponding 
to this time (Figure 7).  The June 15, 2005 has higher ferric iron then ferrous iron 
indicating export.  The sampling time of June 16, 2005 and 30 cm depth has no iron of 
either species as reflected by the flat potentiogram (Figure 7).  This potentiogram 
corresponds to oxidation of the column with hydrogen peroxide.
The curve from -0.2 to -1.2 represents the 1 electron redox conversion from ferric 
to ferrous iron.  The curve from -1.2 to -0.2 V represents the 1 electron conversion from 
ferrous to ferric iron.  Control of the potential ramp allows for identification of specific 
redox couples that would not be possible with only a voltmeter and reference electrode.  
41
The ability of the potetiostat to measure very small amounts of iron allows for 
identification of very small changes in the redox couple concentration ratio.  The column 
effluent is in a concentration range that may not interfere with detection of phytic acid as 
ferric and ferrous phytate.  
Ferric and Ferrous phytate should be present in the effluent.  If ferric or ferrous 
phytates are undetectable by H-NMR sequestration by aluminum sesquioxides present in 
the Elkton soil at a level of 23% could be the cause.  If iron complexes of phytic acid are 
undetectable in the effluent then a further experiment in which phytic acid in excess of 
the absorption capacity of the aluminum oxides present in the column will be conducted.  
Conclusions
In order to understand fate and transport of phytic acid it is essential to determine 
pH driven charge speciation of the molecule. The molecule has twelve protons that are 
responsive to changes in pH.  Phytic acid due to its high mass to charge ratio is an 
excellent chelator and can participate in metal ligand interactions that make the fate and 
transport of several metal phytate complexes interesting environmentally. Iron is present 
in many soil systems making it a potentially important complex of phytic acid and one 
that is likely to be found at environmentally significant quantities.  Phytic acid does not 
have an oxidation reduction potential but can form complexes that are redox responsive.  
We have shown that both oxidized and reduced iron complexes of phytic acid readily 
form in solution and others have shown that phytic acid represents a large pool of organic 
phosphorus in soil and manure (Jayasundera, S et al. 2005; Hansen et al. 2004; Turner et 
al. 2001). Ferric and ferrous iron are forming complexes with phytic acid that can persist 
42
in solution and resist dephosphoralation by the enzyme phytase making ferrous phytate a 
compound with the potential to be exported from soil systems to surface waters.  
The experimental kinetic constants derived from proton nuclear magnetic 
resonance indicate that ferrous phytate forms faster and dissociates at a slower rate then 
ferric phytate. The H-NMR derived findings are supported by the overall enzymatic 
dephosphoralation recoveries of phosphate over a two day period. In anoxic ground 
water ferrous phytate has the potential to resist microbial decomposition from the enzyme 
phytase.  This ability to persist may enable ferrous phytate to be transported by 
subsurface leaching.
Applications of manure to pastures and cropped fields provide regular imputes of 
phytic acid that can be stored as ferric phytate and exported in late winter and early 
spring months when conditions are right.  The water table is generally high due lack of 
evapotranspiration and soils can rapidly become reducing due to the height of the water 
table and or microbial activity.    Concentration of industrialized livestock production and 
the economic unfeasibility of moving manure to away from production sites lead to 
stockpiling and composting of manures in areas that can not support land application as a 
strategy for removal.  Large stores of manure rich in organic phosphorus may increase 
the potential to leach organic phosphorus to ground water and eventually surface waters.
It is widely believed that the major transport processes mobilizing phosphorus 
from soil systems to surface waters is overland flow of sediment attached phosphorus and 
dissolved phosphorus in flood waters.  Given the recent work by Karl, 2000 and Hudson, 
2000 in separate papers indicating that rapid turnover of phosphorus not the quantity is 
the norm in most fresh water systems and in oligotropic marine systems and that 
43
phosphorus is the limiting nutrient in fresh water systems then all transport mechanisms 
of  phosphorus become important to the overall phosphorus budget.  
The relative contributions of phosphorus to surface waters from overland flow 
processes and leaching is unlikely to be spatially uniform.  Areas prone to leaching
phosphorus to ground water and surface water can potentially be correlated to landscape 
features and soil properties.  Anoxia in soil pore water would be a requirement for the 
transport of ferrous phytate to surface waters.  Landscape features that contribute to 
anoxia in pore water are drainage class, organic content and slope.  
44
References
Anderson, G., 1980. Assessing organic phosphorus in soils. In The Role of Phosphorus 
      in Agriculture.  F.E. Khasawneh et al. (eds) ASA Madison WI.  411-431. 
Bar-Yosef B., Chang A. C. and Vega S. 1993. Organic P Transformation Reactions,   
     and Transport in Soils Monitored by 31P NMR Spectroscopy. Bard IS-1610-
     89.
Brady, N. C., Weil R. 2002. In The Nature and Properties of Soils. Saddlebrook, 
     NJ, Prentice Hall.
Brinch-Pedersen, H., Sorensen L. D., and Holm P.B. 2002. Engineering crop 
     plants: getting a handle on phosphate. TRENDS in Plant Science 7(3): 118-
     125.
Butler, J. S and Coale, F.J. 2005. Phosphorus leaching in manure-amended atlantic   
coastal plain soil. J.Environ. Qual. 34:370-381.
Celi, L., Lamacchia, S., Marsen, F.A., Barberis, E.  1999. Interaction of inositol 
     hexaphosphate on clays: adsorption and charging phenomena. Soil Science.    
  164(8):574-585.
Clark, L.L., Ingall, E.D., Benner R. 1999.  Marine phosphorus is selectively 
remineralized.  Nature. 363: 426-426.
Cosgrove, D.G. 1977.  Microbial transformation in the phosphorus cycle. In Advances in 
     Microbial Ecolgy. M. Alexander (ed), Plenum Press, NY 95-134.
Champagne, E.T. 1988. Effects of pH on mineral-phytate, protein-mineral-phytate and   
45
mineral fiber interactions.  Possible consequences of atrophic gastritis mineral 
bioavailability from high-fiber foods.  Journal of the American College of Nutrition. 
v7 (6).
Cheryan, M. 1980. Phytic Acid Interactions in Food Systems.  Crit Rev., Food Sci Nutr.    
     13(4): 297-335.
Dao, T. 2003. Polyvalent cation effects on myo-inositolhexakisdihydrogen   
phosphate enzymatic dephosphorylation in dairy waste-water. J. Environ.    Qual. 
32:694-701.
Gburek, W.J., Sharpney, A.N., Pionke H.B. 1996.  Identification of critical source areas 
     for phosphorus export from agricultural catchments. In Advances in Hillslope 
     Processes, Vol. I, Anderson M.G. and Brooks S. M. (eds) JWiley and Sons Ltd. 
     263-282.
Graf, E (ed.) 1986. Phytic Acid: Chemistry and Applications. Pilatus Press, Minnesota
Hansen J.C., B.J. Cade-Menton, and D.S. Strawn. 2004. Phosphorus speciation in 
manure-amended alkaline soils. J. Environ. Qual. 33:1521-1527.
Hamilton, P.A., Denver, J.M., Phillips, P. J., Shedlock., R. J. 1993. Water quality 
assessment of delmarva peninsula, Delaware, Maryland, and Virginia    
effects of agricultural activities on, and distribution of, nitrate and other     
 inorganic constituents in the surface aquifer.  US Geological Survey, 
  Towson, Maryland.   
Holford, I.C.R. and Patrick Jr, W.H. 1979.  Effects of reduction an pH change on 
     phosphate sorption and mobility in an acid soil.  Soil  Sci. Soc.Am. J. 43:292-297.
Hudson, J.J., Taylor, W.D., and Schindler, D.W.   2000.  Nature. 406, 54-56.
46
Jayasundera, S., W.F. Schmidt, J.B. Reeves and T. Dao. 2005. Direct 
31
P NMR
spectroscopic measurement of phosphorous forms in bovine manures.  Int. J. Food, 
Agri., and the Environ.  Accepted by Journal:  1/10/05.  In press.
Karl, D.M. 2000.  Phosphorus, the staff of life.  Nature. Vol 406. 31-32.
Levitt, M.H.  2003.  Spin Dynamics.  J Wiley and Sons, Inc.  NY.  
Morel, F. M.M. and Hering J. G.  1993.  Principals and applications of aquatic chemistry.
     J Wiley and Sons, Inc.  NY.
Murphy, J. and Riley, J.P.  1962.  A modified single solutionmethos for the determination 
of phosphate in natural waters.  Anal. Chem. Acta., 27:31-36.
Pallauf, J. and Rimbach, G. 1997.  Nutritional Significance of Phytic Acid and Phytase. 
      Arch Anim Nutr., v50: 301-319. 
Richardson, J.L and Vepraskas M.J.(eds) 2002. Wetland Soils. New York, CRC Press
SAS Institute. 1989. SAS user?s guide. SAS Inst., Cary, NC.
      Schmidt, M.F. 1993. Maryland?s Geology, Tidewater Publishers. 
Sims, J.T., Simard, R. R and Joern, B.C.  1998.  Phosphorus Loss in Agricultural 
Drainage:  Historical Perspective and Current Research. J. Environ. Qual. 27:277-
293.  
Stewart, J.W.B., and H. Tiessen. 1987. Dynamics of soil organic phosphorus. 
      Biogeochemistry. 4: 41-60.
Strumm, W. and Morgan J.J. 1996. Aquatic Chemistry.  J Wiley and Sons, Inc.  NY.
Turner B.J., Mahieu N. and Condron L. M. 2003.  The phosphorus compostion of 
     temperate pasture soils determined by NaOH-EDTA extraction and solution 31P  
     NMR spectroscopy.  Organic Geochemistry. 34 (8) 1199-1210.
47
Turner B.J., P. M. Haygarth. 2001. Biogeochemistry-Phosphorus solubilization in 
rewetted soils. Nature. 411(6835): 258-258.
Young, E.O. and Ross D.S.  2001.  Phosphate release from seasonally flooded soils.  J. 
Environ. Qual.  30:91-101.