Organic Ligand and pH Effects on Isotopically Exchangeable Cadmium in Polluted Soils

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DIVISION S-2—SOIL CHEMISTRY

Organic Ligand and pH Effects on Isotopically Exchangeable Cadmium in Polluted Soils

Richard N. Collins^*^,a, Graham Merrington^a, Mike J. McLaughlin^a^,b and Jean-Louis Morel^c

^a Dep. of Soil and Water, Adelaide University, PMB No. 1, Glen Osmond, South Australia 5064, Australia
^b CSIRO Land and Water, PMB No. 2, Glen Osmond, South Australia 5064, Australia
^c Laboratoire Sols et Environnement, ENSAIA-INRA/INPL, 2 avenue de la Forêt de Haye, BP 172, F-54505 Vandoeuvre-les-Nancy, France

* Corresponding author (collins{at}drecam.cea.fr)

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
REFERENCES

Organic ligands excreted by plant roots and pH changes in therhizosphere are two factors that may modify the phytoavailabilityof Cd. The effect of these components on the quantity (isotopicallyexchangeable) and intensity (distribution between the solidand solution phases) of Cd in a polluted acidic and calcareoussoil was examined in detail using a batch experimental system.The organic ligands included (0.25–5 mM) sodium tartrate,the free acid and sodium salt of citrate, histidine, and deoxymugineicacid (DMA). A reduction of pH was identified as the mechanismof Cd solubilization in the presence of some ligands. In othercases, however, organic ligands caused greater Cd solubilizationthan that because of pH changes alone. It was concluded thatorganic ligands might increase solution concentrations of Cd,in both soils, through a number of reaction mechanisms otherthan decreasing pH (e.g., varying the surface charge of thesoil, cation exchange, aqueous metal complexation, etc.). Inthe acidic soil a reduction of pH from 5.7 to 3.8 only increasedthe quantity of isotopically exchangeable Cd (E value) by 17%,thus, indicating the existence of a recalcitrant nonlabile fractionof Cd in this soil. The organic ligands were also unable tosignificantly alter the E value of Cd. In contrast, the presenceof organic ligands and decreases in pH elevated the E valueof Cd in the calcareous soil by as much as 300%. It is postulatedthat conditions in the rhizosphere may not only increase thesolution concentration of Cd, but also increase the quantityof phytoavailable Cd (L value).

Abbreviations: DMA, deoxymugineic acid • E, isotopically exchangeable Cd • ICP-AES, inductively coupled plasma atomic emission spectroscopy • K_d, distribution coefficients

INTRODUCTION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
REFERENCES

PLANTS MAY MODIFY the physicochemical reactions of Cd in thesoil environment (McLaughlin et al., 1998). Plant-induced changesof pH in the rhizosphere have been well documented and it iswell known that pH has a critical influence on the distributionof Cd between the solid and solution phases of soils (Christensen, 1984;Tiller et al., 1984). Furthermore, as analytical techniquesto measure plant-derived organic ligands in soils have improved,it is apparent that they are far more ubiquitous in the rhizospherethan originally assumed (Harter and Naidu, 1995; Jones, 1998).

Metal sorption to the solid phase of soils may be enhanced ifcomplexation with an organic ligand results in an aqueous metal-ligandcomplex that has a high affinity for the soil solid phase (McBride, 1985).Similarly, the sorption of organic ligands may increaseCd sorption to soil surfaces by either increasing the negativeelectrostatic potential on the surfaces, which adsorb Cd, orby binding directly with the aqueous cation (Haas and Horowitz, 1986;Naidu and Harter, 1998). The presence of organic ligandsmay also inhibit the crystallization of some Fe (hydr)oxides.As the negative surface charge of these (hydr)oxides may beincreased, the capacity for metal adsorption may also be elevated(Xue and Huang, 1995).

On the contrary, organic ligands may also stimulate the solubilizationof Cd through a number of processes other than simple aqueousmetal complexation reactions (Elliott and Denneny, 1982; Mench and Martin, 1991;Naidu and Harter, 1998). For example, sorptionof positively charged organic ligands might increase solutionconcentrations of Cd by directly competing for cation-adsorptionsites or by reducing the negative electrostatic potential onsorption surfaces (Levy and Francis, 1976; Chubin and Street, 1981).Organic ligands may also promote the desorption of Cdby dissolving minerals which adsorb the metal (Boyle and Voight, 1973;Jauregui and Reisenauer, 1982; Pohlman and McColl, 1986;Dinkelaker et al., 1989). Similarly, it is also possible thatorganic ligands may dissolve Cd precipitates in soils. As organicligands may induce changes in soil pH (Dinkelaker et al., 1989),solubilization of solid bound Cd may take place because of decreasesin pH. However, soil solution pH changes induced by plant-derivedorganic ligands are currently difficult to predict because itis largely unknown if they are excreted as the free acid orthe alkali metal salt (Dinkelaker et al., 1989; Jones, 1998;Sakaguchi et al., 1999). As such, the former process may increasethe solution concentration of Cd by decreasing the pH of thesoil solution, whereas the latter may reduce concentrationsof Cd in solution by inducing a rise in pH. In fact, distinctionsbetween pH changes and other mechanisms of soil Cd solubilizationin the presence of organic ligands have rarely been made (Naidu and Harter, 1998).Moreover, most studies have stressed metaladsorption and desorption reactions, which are surface processes,while precipitation and dissolution reactions may also be extremelyimportant. This is particularly true for soils that are alreadypolluted with Cd (Jopony and Young, 1994).

Isotopic dilution has been a useful technique to quantify thesurface-adsorbed phase of an element that is in equilibriumwith the solution phase (McAuliffe et al., 1947; Sumner and Bolt, 1962).In other words, a radioactive isotope, added toa preequilibrated soil suspension, will rapidly (hours to days)partition itself between the solid and solution phases in exactlythe same manner as the surface-adsorbed stable element in equilibriumwith the solution phase (McAuliffe et al., 1947). Therefore,the quantity of surface-adsorbed stable element, commonly referredto as the labile pool or E value, may be determined simply bymeasuring the distribution of the radioisotope between the solidand solution phases (K_d) and the concentration of stable elementin solution (M):

[1]

Using the same principle, plants may be grown on isotopicallyequilibrated soils and the plant material used as the mediumto measure concentrations of the radioactive and stable element—therebyreplacing the soil solution used for determining E values. Althoughconceptually the same, results using plants as the samplingmedium have been termed L values (Larsen, 1952).

It is these techniques which have provided evidence that theplant uptake of Cd in polluted soils may not always be limitedto surface processes in the rhizosphere (Smolders et al., 1999;Gerard et al., 2000; Hutchinson et al., 2000). For example,Smolders et al. (1999) found that the labile pool of soil Cdavailable to Triticum aestivum L. (the L value) always exceededthe isotopically exchangeable pool of Cd measured in the laboratory(the E value) on 10 soils varying in pH (4.5–7.2) andCd contamination. It was also observed that variations of pHacross soils affected isotopically exchangeable Cd, but thisphenomenon was not considered in depth. In addition, it hasalso consistently been demonstrated that high concentrationsof EDTA (a synthetic organic ligand with strong metal-complexingabilities) increases the Cd E value of soils—presumablyby the dissolution of Cd from occluded or interior sites inthe soil (Nakhone and Young, 1993; Stanhope et al., 2000).

Therefore, the exudation of organic ligands and plant-inducedchanges of pH may arguably be two of the most important variableslikely to affect the phytoavailability of Cd in the rhizosphere(Eriksson, 1989; Mench and Martin, 1991; Cieslinski et al., 1998).Despite this fact, extensive research identifying theforms of phytoavailable soil Cd and the factors controllingits quantity is still lacking in the literature. As this knowledgeis essential to further develop sound and cost-effective remediationstrategies, this study was conducted to determine the effectsof H⁺ and plant-derived organic ligands on isotopically exchangeableCd in two polluted soils varying in pH.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
REFERENCES

Soils
The A_p horizon of two soils (Hapludalfs), from a series of limedsilt loam brown soils, was taken from Région Nord-Pasde Calais, France. The soils were located adjacent to two differentZn smelters and have been subject to Cd, Pb, and Zn pollutionby the deposition of atmospheric particles. The first soil wascalled the ‘acidic soil’ while the other soil containinga proportion of calcium carbonate was termed the ‘calcareoussoil’. A brief description of their physical and chemicalproperties is provided in Table 1. Before use, the soils wereair-dried and sieved to <2 mm.

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Table 1. Selected physical and chemical properties of the two soils. A 1:5 soil/solution ratio was used to measure pH after 1 h of equilibration. Phosphate was calculated after sodium bicarbonate extraction. Major elements and cation-exchange capacity (CEC) were estimated by ammonium chloride extraction. Total Cd, Pb, and Zn was measured after aqua-regia digestion.

Organic Ligands and Chemicals
Calcium chloride (Prolabo, Paris, France), calcium nitrate (Prolabo,Paris, France), disodium-L-tartrate (Aldrich-Chemie, Steinheim,Germany), trisodium-citrate (Aldrich-Chemie, Steinheim, Germany),L-histidine (Sigma, Steinheim, Germany), and citric acid (Merck,Damstadt, Germany) were all used as received. A stock solutionof EDTA (Prolabo, Paris, France) was made by dissolving thefree acid in high purity water (18 M ${Omega}$ -cm resistance) bufferedto pH 7 with 29% NH₄OH. Deoxymugineic acid, a phytosiderophoreexcreted by some graminaceous species under Fe deficiency conditions,was collected as root exudates from Zea mays L. (cv. Zeamx,PI3394, Zeneca Ag. Products, Richmond, CA) grown under Fe-deficientconditions in nutrient solution according to the methodologyof von Wiren et al. (1996). After concentration on a cation-exchangecolumn (AG 50W-X8 resin in the H⁺ form, 200–400 mesh,Bio-Rad, Richmond, CA) (Takagi et al., 1984) the protonatedDMA was desalted by dialysis using a 100 MWCO membrane (Spectrum,Laguna Hills, CA). The identity of DMA was confirmed by electrospraymass spectrometry using flow injection analysis (Finnigan MATTSQ 700, San Jose, CA) and its purity by anion chromatography,as described below.

Determination of Distribution Coefficients and E Values of Cadmum
Distribution coefficients (K_d) and E values of Cd in the soilswere measured by batch experiments using 60-mL polyethylenebottles. To these bottles a quantity of air-dry soil, equivalentto 2.5 g of oven-dry soil, was added with 25 mL of solution(e.g., organic ligand). All solutions were prepared with highpurity water. Chloroform (50 µL) was also added at thistime to minimize bacterial activity during isotopic equilibration.

A range of organic ligand concentrations from 0.25 to 5 mM werechosen and DMA was included with experiments using the calcareoussoil. Variations of pH were facilitated by the addition of either100 mM NaOH or HNO₃. The volume of these soil suspensions wasmade to 25 mL with high purity water.

Triplicate samples of each treatment were equilibrated by shakingon an end-over-end shaker at 40 rpm for 24 h. At this time 1mL of carrier-free ¹⁰⁹Cd (0.24–9.41 kBq g^-1 soil) wasadded to the bottles and equilibrated for a further 24 h. Todetermine if these systems had reached equilibrium some bottleswere shaken for an additional 48 h. No statistical difference,at the 0.05 probability level using the test of Newman-Keulsafter ANOVA, was observed between the E value measured at thesetwo equilibration periods using high purity water, 10 mM CaCl₂,10 mM Ca(NO₃)₂, 0.5 mM solutions of all the organic ligands,and 5 mM solutions of citric acid and sodium citrate. Therefore,the shorter equilibration time was used throughout the experiments.

After equilibration the bottles were centrifuged at 1000 x gfor 5 min to aid phase separation. The supernatant was filteredthrough cellulose nitrate filters (0.025 µm) into 20-mLpolyethylene bottles and acidified to pH <2 with concentratedHNO₃ (Gerard et al., 2000). One milliliter was taken to measurethe residual radioactivity of ¹⁰⁹Cd in solution while the remainderwas refrigerated until analysis for stable Cd.

Protocol for Measuring Organic Ligand Sorption
Organic ligand sorption to the solid phase of the soils wasdetermined by adapting the methodology of Jones and Brassington (1998)to the protocol used to determine the K_d and E values(i.e., 1:10 soil/solution ratio). After the addition of theorganic ligand solutions and chloroform to the bottles containingthe soils, they were shaken at 320 rpm for 10 min and then centrifugedat 1000 x g for 5 min to aid phase separation. Aliquots of <100µL were taken from the supernatant and the concentrationof organic ligand remaining in solution was analyzed by anionchromatography (described below). The amount of sorption wascalculated by subtracting the quantity of organic ligand measuredin solution from the initial concentration added. The concentrationof organic ligand remaining in solution was also quantifiedafter isotopic equilibration. The sorption of DMA was not measuredin these experiments because of a lack of suitable instrumentationto accurately quantify this ligand. However, the pH of the soilsuspensions was measured at all sampling times.

Analyses
The amount of ¹⁰⁹Cd added to the soil suspensions and that remainingin solution after equilibration was quantified by ${gamma}$ -spectrometry(Cobra 5003, Packard, Meriden, CT). Solution concentrationsof stable Cd were analyzed by inductively coupled plasma atomicemission spectroscopy (ICP-AES) (JY 238, Jobin Yuon, Paris,France). As determined by the analyses of spiked samples andsamples diluted with high purity water, the analytical errorassociated with ICP-AES measurements was <2% of the solutionconcentration of Cd. The detection limit of Cd using ICP-AESwas limited to 0.5 µg L^-1. Solution concentrations oftartrate and citrate were measured using eluent-suppressed conductivitydetection following NaOH gradient separation (1–35 mM)on a Dionex AS-11 anion-exchange analytical column equippedwith a Dionex AG-11 guard column (Dionex Corp., Sunnyvale, CA).The purity of DMA from other organic acids and salts, afterdialysis, was also established by the same methodology. Histidinewas separated by the same procedure as that used for the organicacids but was quantified using direct-UV detection at 210 nm.Using this methodology the limit of detection for histidinewas 10 µM.

Equations and Statistics
The K_d of Cd in the soils was calculated by the following equation:

[2]
where R is the quantity of carrier-free¹⁰⁹Cd added (Bq L^-1), r is the quantity of ¹⁰⁹Cd remaining insolution after equilibration (Bq L^-1), and L/S equals the liquid/solidratio (L kg^-1 soil)

The E value calculated from Eq. [1] only represents surface-adsorbedmetal in equilibrium with the solution phase. Therefore, thetotal solution concentration of metal must be added to the Evalue of Eq. [1] to obtain the total isotopically exchangeablemetal in the soil–solution system (Smolders et al., 1999):

[3]

Equation [3] was used in this study because it is consideredthat the total isotopically exchangeable metal best representsthe quantity of metal available for plant uptake (Smolders et al., 1999).

Statistical differences between treatment means, after ANOVA,were calculated using the test of Newman-Keuls (at the 0.05probability level) using the statistical computer program STATITCF,version 5 (ITCF, Biogneville, France). Nonlinear regressionswere calculated using SIGMAPLOT, version 5.0 (SPSS Science,Chicago, IL).

RESULTS AND DISCUSSION

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
REFERENCES

Sorption of Organic Ligands
In general, there was little sorption of the organic ligands,except histidine, in both soils (Table 2). For most ligands,sorption was positively related to increases in the solutionconcentration of the ligand. However, as pH was not bufferedin these experiments, varying the concentration of most ligandsresulted in changes of pH (data not shown). Nevertheless, despiteprevious results indicating that pH may affect citric acid andsodium citrate sorption to acidic soils at concentrations >2mM (Jones and Darrah, 1994), there were no significant differencesbetween the sorption of these ligands to the soils used in theseexperiments. The sorption of tartrate was also unaffected bysoil type. As sorption of these ligands was unaffected by changesin pH or soil type, it indicates that neither the pK_a of theligand's functional groups, complexation with metals, nor thesurface charge of the soils had any observable effect on theirsorption behavior in these experiments.

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Table 2. Concentrations of organic ligands remaining in solution after adsorption (10 min) and isotopic equilibration (48 h). Results are the mean of triplicate samples. The standard deviation for all measurements was <5%.

In contrast to the organic acids, histidine had a much strongeraffinity to the solid phase of the soils. High levels of histidinesorption to the acidic soil, in comparison with the calcareoussoil, were probably related to the isoelectric point of histidineand pH differences between the soils. Histidine is positivelycharged at pH values <7.47 and negatively charged above thispH, despite the values of pK₂ (pH 6.0) and pK₃ (pH 9.3). Therefore,in soil suspensions containing the acidic soil (pH range 6.5–6.7),histidine was being sorbed as a positively charged ligand. Incontrast, the pH of the suspensions containing the calcareoussoil (pH range 8.2–8.4) was higher than the isoelectricpoint of histidine, which coincided with less sorption to thissoil.

Although the sorption of DMA was not measured, its sorptionbehavior should be similar to that observed for the negativelycharged organic acids because its isoelectric point would beat a pH between pK₂ (pH 2.76) and pK₃ (pH 3.4) (Sugiura et al., 1981).

Organic Ligand Concentrations after Isotopic Equilibration
Preliminary results, as measured by plating techniques, indicatedthat the addition of 50 µL of chloroform to the soil suspensionsonly minimized microbial activity. Therefore, to accuratelyassess the influence of organic ligands on the chemistry ofCd in these soils, the solution concentration of the ligandafter isotopic equilibration was also measured.

In the acidic soil, significant decreases in the solution concentrationof sodium citrate and tartrate were observed at 0.25 mM andfor citric acid from 0.25 to 1.0 mM. At the conclusion of theequilibration period histidine was also not detected for alltreatments in the acidic soil. In the calcareous soil, significantdecreases in the concentration of citric acid and sodium citrateat 0.25 mM and histidine at all concentrations were observed.

After equilibration it was noted that the pH of these solutionshad decreased by as much as one pH unit (data not shown). Therefore,decreases in pH may have (i) increased the quantity of positivelycharged histidine molecules and, thus, enhanced histidine sorption,or (ii) increased the positive surface charge of the soils enhancingsorption of negatively charged metal-ligand complexes or theligands themselves. A reduction in the solution concentrationof these ligands may also have been simply the result of biodegradation.

Organic ligands other than citrate, tartrate, and histidinewere not detected in the solutions. Therefore, changes in theK_d or E value of Cd in the presence of the added ligands wasnot due, in part, to microbially produced organic ligands. Nevertheless,it was assumed that further losses of organic ligands from solution,after the sorption experiments (>10 min), were a result of biodegradation.Hence, discussion on the effects of organic ligands on the behaviorof Cd in these soils is based on the concentration of ligandremaining in solution, after isotopic equilibration, and thequantity of ligand, which was rapidly sorbed to the soil solidphase. This assumption may add a source of minor uncertaintyto the conclusions of Cd solubilization mechanisms in the presenceof some of these ligands.

The Distribution Coefficients of Cadmium as Influenced by pH
The K_d values of Cd in the soils were strongly pH-dependent(Fig. 1) , confirming previous observations on the distributionof Cd between the solid and solution phases of soils (Christensen, 1984;Tiller et al., 1984; Elliott et al., 1986; Filius et al., 1998).Over the pH ranges examined in these soils, the partitioningof Cd between the solid and solution phases was characterizedby sigmoidal shaped curves. At lower pH values these curveswere distinguished by steep changes in the quantity of Cd associatedwith the solid phase. The natural pH of the acidic soil afterisotopic equilibration (pH 5.7) was located within this pH range,whereas the natural pH of the calcareous soil (pH 7.5) representedthe end point of this range.

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Fig. 1. The distribution of Cd between the solid and solution phases (represented as K_d) for the soils as affected by changes of pH. Values and error bars represent the mean and standard deviation of triplicate measurements. The five-parameter nonlinear regression fitted for the acidic soil was K_d = 48.4 + 2499/(1 + exp[-(pH-5.77)/0.18]^0.86: R² = 0.99, P < 0.0001 and for the calcareous soil was K_d = 112.4 + 3421/(1 + exp[-(pH-7.49)/0.0034]^0.0112: R² = 1.00, P < 0.0001. See text for explanation of equations.

Sharp variations in the K_d of Cd with small changes of pH havecommonly been attributed to the preferential adsorption of CdOH⁺(Bruemmer et al., 1988; Tiller, 1996; Naidu and Harter, 1998),the adsorption of Cd²⁺ (Anderson and Christensen, 1988; Barrow and Whelan, 1998;Sauvé et al., 2000), proton competitionfor adsorption sites (Boekhold et al., 1993), variations inthe negative surface-charge density of the soil (Naidu et al., 1994),and acid catalyzed dissolution of reactive oxide sites(Elliott and Huang, 1979) or precipitates. Based exclusivelyon the K_d values reported here, adsorption and desorption reactionsof Cd are experimentally indistinguishable from precipitationand dissolution reactions of Cd minerals or precipitates.

Effect of Organic Ligands on the Distribution Coefficients of Cadmium in the Acidic Soil
The type and concentration of organic ligand affected the distributionof Cd between the solid and solution phases of the acidic soil(Fig. 2) . To distinguish between pH and other processes (e.g.,chelation) affecting K_d, the data were compared with those predictedat the same pH value in the absence of the ligand. The valuesof K_d (y) over the pH range examined in this soil were obtainedby fitting the data presented in Fig. 1 by a five-parameternonlinear regression:

[4]
where y0 isthe minimum K_d value, a is (maximum K_d - minimum K_d), x is pH,x0 is pH₅₀, b is a constant describing the linearity of theregression, and c is a measure indicating the sigmoidal qualityof the regression.

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Fig. 2. The K_d of Cd in the acidic soil as affected by organic ligands compared with estimated values at the same equilibrium pH in the absence of ligand. Values and error bars of K_d in the presence of ligands represent the mean and standard deviation of triplicate measurements. The K_d values in the absence of ligands were calculated using the five-parameter nonlinear regression derived from the data of Fig. 1 and the mean pH values measured from triplicate samples containing the ligands.

When these data were compared with the results obtained forthe organic ligands it was found that histidine increased thesolution concentration of Cd over that estimated at the samepH in the absence of the ligand. This is an interesting resultconsidering that histidine was significantly sorbed to the soilsolid phase at all concentrations and was not detected in solutionafter equilibration. Therefore, as histidine was sorbed as apositively charged ligand, it was desorbing Cd by either reducingthe negative electrostatic potential of the soil surface andby directly competing for the same adsorption sites.

Although a general increase in the solution concentration ofCd occurred as concentrations of citric acid and tartrate increased,the proportion accounted for by pH also increased. In conjunction,increasing concentrations of these ligands resulted in a loweringof the equilibrium pH of the solution. Therefore, if increasingligand concentrations are associated with decreases in pH thenthe K_d of Cd becomes increasingly controlled by the concentrationof H⁺ in solution. These observations are consistent with thefact that the stability of Cd-ligand complexes decrease witha reduction in pH.

At higher pH values, where the K_d was lower than that predictedby pH alone, there are a number of processes that could havebeen responsible for increased Cd desorption and dissolutionin the presence of sodium citrate and tartrate. Calculationsmade with the computer program GEOCHEM-PC, version 2.0 (Parker et al., 1995)indicated that the metal-ligand complexes of citrateand tartrate either carried a net zero or negative charge inthe pH range examined in these experiments. Similar calculationspredicted that the ligands themselves had a net negative charge.Therefore, elevated solution concentrations of Cd in the presenceof the sodium salts of citrate and tartrate were not a resultof a process similar to that observed for histidine. It is alsohighly unlikely that Na⁺ from the organic ligand solutions wascontributing to Cd desorption based on the results of Naidu and Harter (1998)and Naidu et al. (1994). Therefore, sodiumcitrate and tartrate were increasing the solution concentrationof Cd by forming nonsorbing soluble complexes with Cd therebyreducing Cd²⁺ (and possibly CdOH⁺) activities in the soil solutionwhich would lead to the desorption of solid bound exchangeableCd or the ligands were dissolving Cd precipitates or adsorptionsurfaces (e.g., Fe [hydr]oxides).

Effect of Organic Ligands on the Distribution Coefficients of Cadmium in the Calcareous Soil
The presence of organic ligands also decreased the K_d of Cdin the calcareous soil (Fig. 3) . A sigmoidal regression wasalso applied to the data in Fig. 1 to distinguish between pHand other possible mechanisms that may have increased the solutionconcentration of Cd in this soil. Increasing concentrationsof citric acid decreased the pH of the soil solutions and theK_d's of Cd were not significantly different to those valuescalculated at the same pH in the absence of the ligand. Thisobservation is similar to the results of the experiments withthe acidic soil where decreases of pH generated metal-ligandinstability and Cd desorption and dissolution was controlledby the solution concentration of H⁺.

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Fig. 3. The K_d of Cd in the calcareous soil as affected by organic ligands compared with estimated values at the same equilibrium pH in the absence of ligand. Values and error bars of K_d in the presence of ligands represent the mean and standard deviation of triplicate measurements. The K_d values in the absence of ligands were calculated using the five-parameter nonlinear regression derived from the data of Fig. 1 and the mean pH values measured from triplicate samples containing the ligands.

It was more appropriate to compare the ability of the otherligands to bring Cd into solution, in comparison with the acidicsoil, because the pH of these solutions were in the range wherethe K_d of Cd was largely unaffected by variations of pH. Thecapacity of these ligands to bring Cd into solution followedthe order: DMA > histidine > citrate > tartrate. This orderprovides good evidence that chelation processes were controllingthe solution concentrations of Cd as it reflects the known conditionalstability constants of the dominant Cd–ligand complexeswithin this pH range (Parker et al., 1995). Although the thermodynamicstability constants (log K) of Cd-DMA complexes are unknown,the conditional log K's (conditional as they are adjusted forpH) of the dominant Cd–ligand complexes with the otherligands are (Parker et al., 1995): 5.96 (>98% CdHistidine^-),4.58 to 4.69 (>99.9% CdCitrate^-), and 3.62 (100% CdTartrate°).Furthermore, this relationship would not be confounded by thefact that a significant quantity of histidine, at initial concentrationsof 0.5 and 1.0 mM, was sorbed to the soil. For example, despitethe solution concentrations of histidine being significantlylower than those of citrate, the order of Cd solubilizationwould still hold as the conditional stability constant of theCd–histidine complex is >19-fold higher than that forthe dominant Cd–citrate complex. In addition, it seemsunlikely that cation-exchange processes in the presence of 0.25mM histidine were solely responsible for the relatively largedecrease in the K_d of Cd observed in this treatment (in comparisonto the acidic soil). The detection limit for histidine was approximately10 µM. Therefore, it is quite plausible that histidine,at concentrations below the limit of detection, was also increasingthe solution concentration of Cd through aqueous complexationprocesses.

Further evidence that chelation was affecting the solubilizationof Cd and not the dissolution of adsorbing surfaces, was foundwith increases in the concentration of Fe following a slightlydifferent order to that observed for Cd: DMA > citrate > histidine ${cong}$ tartrate (data not shown). If the dissolution of adsorbingsurfaces, such as Fe (hydr)oxides, was primarily responsiblefor the solubilization of Cd, then increases in the solutionconcentration of Cd should be expected to reflect that observedfor increases in solution concentrations of Fe.

Cadmium E Values as Affected by pH and Organic Ligands
Despite the large effect that changes of pH had on the distributionof Cd between the solid and solution phases in the acidic soil,it had little consequence on the E value. For example, onlyat pH 3.8 was the E value significantly higher than that measuredat pH values > 5.9. Furthermore, the presence of organic ligandsdid not significantly alter the E value of Cd in this soil whencompared with values calculated at the same pH in the absenceof the ligand (Fig. 4) . Further experiments conducted with20 mM EDTA also indicated that the E value was indifferent tohigh concentrations of organic ligands with strong metal-complexingcharacteristics (E = 15.1 mg kg^-1). These results indicate thatthe E value of this soil is a stable pool of metal despite itonly representing 65% of the total soil Cd. For example, whenthe equilibrium pH was reduced to 3.8 this percentage only increasedto 75%, suggesting that acid digestion may be necessary to liberatethe remaining nonisotopically exchangeable Cd from interioror occluded sites. As such, under relevant environmental conditions,a part of the Cd in this soil remains nonisotopically exchangeableand, furthermore, does not readily replenish that portion whichis isotopically exchangeable.

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Fig. 4. The E value of Cd in the acidic soil as affected by pH and the presence of organic ligands. The fitted line is a linear regression of the pH data where E = -0.8683pH + 18.223: R² = 0.91, P > 0.001. The symbol ( ${diamondsuit}$ ) and error bars represent the mean value and standard deviation of triplicate measurements of pH. The other symbols represent: (0.25–5 mM) citric acid (x), (0.25–5 mM) sodium citrate (o), (0.25–1 mM) histidine ( ${square}$ ), and (0.25–1 mM) tartrate ( ${Delta}$ ).

In contrast, despite having similar total Cd contents to theacidic soil, only 19% of the Cd in the calcareous soil was isotopicallyexchangeable in water (Table 3). However, a reduction of pHfrom 7.5 to 5.8 was able to triple the size of the E value inthis soil. Variations of pH in the calcareous soil also resultedin E values that could be characterized by a five-parameternonlinear regression (as used for the K_d data). When the E valuesmeasured in the presence of citric acid were compared with thisregression no significant difference between these two datasets were observed (Fig. 5) . This result confirms the K_d data,where it was found that the sole effect of citric acid on thebehavior of Cd in this soil was through its ability to supplyH⁺ ions to the system.

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Table 3. The E value of Cd as affected by changes in soil suspension pH.

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Fig. 5. The E value of Cd in the calcareous soil as affected by pH and the presence of citric acid. The solid line represents the fitted five-parameter non-linear regression of E = 3.44 + 7.83/(1 + exp[-(pH-8.23)/-0.41]²¹: R² = 0.99, P < 0.0001. Hashed lines represent 95% confidence limits. The symbol ( ${diamondsuit}$ ) represents the mean E value of Cd, in the absence of ligands, measured with triplicate samples. The symbol (x) and error bars represent the mean value and standard deviation of triplicate measurements of (0.25–5 mM) concentrations of citric acid.

The other organic ligands, with the exception of 0.5 mM sodiumtartrate, also had the capability to increase the quantity ofisotopically exchangeable Cd in the calcareous soil (Fig. 6) .Variability in the results between the replicates of 0.25 mMsodium tartrate were high and an inspection of the solutionconcentrations of Cd, Zn, and Fe indicated that these solutionshad been contaminated with stable metals. As a result, the datafor this treatment are not reported. Nevertheless, despite theE value generally increasing with the concentration of the otherorganic ligands, no comprehensive relationship could be ascertained.

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Fig. 6. The effect of organic ligands on the E value of Cd in the calcareous soil. Values represent the ratio of the E value measured in the presence of the ligand against that measured in the absence of the ligand at pH 7.5. Symbols and error bars represent the mean and standard deviation of triplicate measurements. The symbols represent: (0.25–5 mM) sodium citrate ( ${circ}$ ), (0.25–1 mM) histidine ( ${square}$ ), (0.5–1 mM) tartrate ( ${Delta}$ ), and (0.25–0.5 mM) DMA (+).

Therefore, based on the fact that the E value represents thetotal quantity of surface-adsorbed element that is in equilibriumwith the solution phase it may be concluded that nonisotopicallyexchangeable Cd brought into equilibrium in this soil consistedof Cd precipitates or mixed solids. Calculations made with GEOCHEM-PCindicated that the solutions were undersaturated with respectto the pure solid phases of the Cd minerals—CdCO₃ andCd₃(PO₄)₂. Therefore, nonisotopically exchangeable Cd was beingmobilized from mixed-metal solid phases or pure Cd mineralswhose solubility has been altered by surface contamination withsoil constituents, such as soil organic matter.

SUMMARY AND CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
REFERENCES

In the present experiments, the E value of the acidic soil measuredin water represented a major portion (if not all) of the Cdthat maybe potentially phytoavailable. This conclusion was supportedby the fact that decreases of pH and variations of solutioncomposition, although greatly effecting K_d, had no significanteffect on the size of the isotopically exchangeable pool ofCd. Based on these observations it is unlikely that conditionsin the rhizosphere would alter the isotopic exchange propertiesof Cd in this soil. Therefore, from a practical point of view,the E value, regardless of the solution composition used forisotopic equilibration, is a good indication of the total quantityof Cd that would be phytoavailable (L value) in this soil. Incontrast, variations of the E value in the calcareous soil indicatedthat isotopically exchangeable Cd measured in water may notbe an accurate representation of all the metal potentially availablein the presence of root-exuded organic ligands or upon acidification.

This study highlights the fact that the E value will only bea reliable indication of the quantity of phytoavailable Cd (Lvalue) under one condition—when the isotopically exchangeableCd is insensitive to changes of K_d. This condition was onlymet on the acidic soil. However, in soils where isotopicallyexchangeable Cd varies with K_d, it will also be possible, butmuch more difficult, to predict the quantity of phytoavailableCd, but only if the K_d of Cd measured in the laboratory determinedE values is exactly the same as the K_d in the rhizosphere. Assuch, in these types of soils, plant-induced decreases of pHand the exudation of organic ligands will increase the quantityof isotopically exchangeable Cd and, therefore, may accountfor previously observed differences between L and E values ofCd (Smolders et al., 1999; Gerard et al., 2000; Hutchinson et al., 2000).

Received for publication October 9, 2001.

REFERENCES

TOP
ABSTRACT
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MATERIALS AND METHODS
RESULTS AND DISCUSSION
SUMMARY AND CONCLUSIONS
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