Redistribution of Metals in a New Caledonia Ferralsol After Microbial Weathering

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DIVISION S-2—SOIL CHEMISTRY

Redistribution of Metals in a New Caledonia Ferralsol After Microbial Weathering

C. Quantin^a, T. Becquer^a^,b, J. H. Rouiller^a and J. Berthelin^*^,a

^a Lab. for microorganism-mineral-organic matter interactions in soil (LiMos), FRE 2440, CNRS, 17, rue Notre-Dame des Pauvres, BP5, F-54501 Vandoeuvre-les-Nancy, France
^b Embrapa CPAC, CP 08223, 73301-970 Planaltina – DF, Brazil

* Corresponding author (bertelin{at}cpb.cnrs-nancy.fr)

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Ferralsols from southern New Caledonia developed on ultramaficrocks are very rich in Fe, Mn, and in other transition metalslike Cr, Ni, and Co. Bacterial weathering of Fe and Mn oxidesperformed in batch experiments increases metal solubilizationparticularly under reducing waterlogged conditions and whenorganic compounds are available as nutrients. Moreover, bacterialweathering can modify the metal distribution through the geochemicalcompartments of the soil. Bacterial reduction of oxides ledto the solubilization of Fe, Mn, Ni, and Co and brought abouta significant metal redistribution into the different geochemicalcompartments of the soil. Selective sequential extractions showedan increase in the metal (Fe, Mn, Co, Ni, and Cr) content ofthe most labile compartments (water-soluble and exchangeable)after microbial weathering. Metal concentrations of amorphousand poorly crystallized Fe oxides also increased significantly.This mineral phase acted as a strong sorbent promoting the coprecipitationof metals with Fe. The Mn oxide compartment decreased significantly,especially under high microbial activity. The metal contentsof the well-crystallized Fe oxide and residual fraction werestable showing that microbial weathering have a limited effecton these compartments. Although the soluble Cr was always nil,Cr was also significantly redistributed into the various geochemicalcompartments (highlighting the rapid sorption of this elementversus its solubilization). Such redistribution processes areimportant to be known and to be quantified to define metal behaviorand improve risk assessment.

Abbreviations: CEL, shredded cellulose treatment • d (subscript), dissolved metals • DCB, dithionite citrate bicarbonate • EDXS, energy dispersive x-ray spectrometer • EXCH, exchangeable, FEOX1, bound to amorphous or poorly crystallized Fe oxides • FEOX2, bound to well crystallized Fe oxides • GLU, glucose treatment • ICP-AES, inductively coupled plasma atomic emission spectroscopy • MNOX, bound to Mn oxides • OM, associated with organics • RES, residual • SOM, soil organic matter treatment • SSE, selective sequential extractions • t (subscript), total element concentration • TEM, transmission electron microscope • WAT, water soluble

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

IN SOUTHERN NEW CALEDONIA, Ferralsols developed from ultramaficrocks are very rich in both Fe and Mn oxides (Nalovic and Quantin, 1972;Schwertmann and Latham, 1986). Other transition metalslike Cr, Ni, and Co are also present in very high concentrations,either adsorbed on the oxides or incorporated into their minerallattice. Recent mineralogical studies showed that most of theNi and around 50% of the Cr were associated with Fe oxide (Becquer et al., 2001b),whereas Co was mainly associated with Mn oxides(Quantin et al., 2002). These observations confirmed that Feand Mn oxides are major scavengers and reservoirs for metalsand control their availability (McKenzie, 1989; Singh and Gilkes, 1992).

Bacterial reduction of Fe and Mn oxides increases metal solubilizationwhen C is highly available as during simulated waterloggingconditions (Quantin et al., 2001). Other studies performed ata toposequence scale in New Caledonia have shown that both DTPA-extractableNi and Ni contents of crops increased in plain soils submittedto waterlogging (Becquer et al., 1995; L'Huillier and Edighoffer, 1996).Depending on soil moisture, both redox potential andbiological activity may control oxide solubilization (Patrick and Jugsujinda, 1992)and heavy metal release and redistribution(Hazra et al., 1987; Han et al., 2001).

Microbial transformation of both mineral and organic soil constituentsleads to the solubilization of metals that can later be renderedunavailable by adsorption or precipitation phenomena (Quantin et al., 2001).Such process may lead to the removal of metalsfrom the soil profile by leaching and to the modification oftheir form and distribution in the solid phase. The knowledgeof these phenomena is important to understand the behavior ofpotentially toxic metals in soils, their potential uptake byplants and their leaching through the soil profile.

The aim of this study is to understand the partitioning andredistribution of metals in specific compartments of the solidphase after microbial weathering and particularly bacterialreduction and dissolution of Fe and Mn oxides. It provides informationon mineral weathering by heterotrophic microorganisms.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Soil Sampling and Analysis
Soil was collected in the Ouénarou forestry station insouthern New Caledonia. It originated from the alluvio-colluvialsoil of the sequence studied and described in details by Becquer et al. (1995)( 2001b). Samples were taken in the subsurface horizon(4–10 cm) of a silt-clay Geric Ferralsol (FAO, 1998) andsieved at <2 mm.

Total C and N in the sample were determined using a CHN 1108Carlo Erba analyzer (Carlo Erba, Milan, Italy). Iron, Mn, Al,and Si concentrations in the sample were determined after alkalinefusion. One gram of lithium metaborate-tetraborate (80–20%[wt/wt]) mixture was added to 100 mg of fine crushed sampleand heated at 1000°C. After the fusion, the resulting pelletwas dissolved in 1% (v/v) HNO₃. The concentration of Co, Ni,and Cr were determined after acid (concentrated HNO₃/HCl; 2:1)digestion of 100 mg of finely ground soil in teflon vesselsheated in a microwave oven. This procedure, that was used formetal analysis in the bulk soil and in the residual compartment(see below), was validated by analyzing a reference material(geostandard BX N, Govindaraju, 1995). The recovery rate forthis sample was up to 93% (93.2% for Cr). Major and trace elementswere measured by inductively coupled plasma atomic emissionspectroscopy (ICP-AES) (Jobin-Yvon 238). Total element concentrationsare denoted Me_t.

Incubation Experiment
Batch incubations were performed with 50 g (or 25 g for controls)of soil in sealed 1000-mL (or 500-mL) glass bottles, supplementedwith 750 mL (or 375 mL) of water as described by Quantin et al. (2001).All incubations were carried out anoxically, underO₂–free N₂ atmosphere, with four replicates per treatment.

Three treatments were performed with different sources of organicmatter. The first received no organic matter supply, so thatindigenous soil organic matter (SOM treatment) was the onlysource of C and nutrients (samples incubated with distilledwater as liquid medium). To simulate organic input, the othertreatments were supplied with 6 g C kg^-1 of soil of either glucose(1 g L^-1; GLU treatment) or shredded cellulose (Whatman 40,0.96 g L^-1; CEL treatment). Total C content was 3.2% in GLUand CEL treatments, whereas it was only 2.6% in the SOM treatment.Flasks with soil were incubated under biotic and abiotic conditions,to distinguish microbial and physicochemical processes. Abioticconditions were obtained by adding 1 g L^-1 of sodium thimerosal.Incubations were conducted in the dark at 28°C for 140 d,with only hand shaking prior to gas sampling.

Bacterial activity was monitored by measuring the C mineralization(infrared analysis of the CO₂ content of the flask headspace)and metal solubilization at various times of incubation (seedetails in Quantin et al., 2001). Metals were determined inbiotic and abiotic treatments by ICP-AES analysis of 0.2-µmfiltered samples. Dissolved metals are denoted Me_d.

Selective Sequential Extraction Procedure
The partitioning of metals among the compartments of the soilsolid phase was investigated indirectly by selective sequentialextractions (SSE). The SSE procedure (Table 1) was a seven-stepprocedure adapted from Leleyter and Probst (1999), modifiedfrom Tessier et al. (1979) and Shuman (1985). The SSE was performedwith 1 g of ground soil in 50-mL polypropylene centrifugationtubes to minimize losses of material. All extractions were performedin duplicate on three replicates of each treatment. In eachextraction series, a standard sample (initial one) was introducedto follow the reproducibility of the procedure.

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Table 1. Selective sequential extraction (SSE) procedure.

After each extraction step, the tubes were centrifuged at 5200x g for 20 min. The supernatants were then filtered through0.45-µm membranes (Sartorius), whereas the residues werewashed with 10 mL of ultrapure water, centrifuged again, andthen the supernatants were pooled. The leachates (extract andrinsing) were then stored in polypropylene bottles or glassvials at 4°C until chemical analysis. The residues weredried at 40°C prior to the next extraction step.

All reagents were of analytical grade or of better quality.Blanks without a soil sample were done for each extraction stepto determine the purity and quality of the procedure.

No satisfactory physicochemical and chemical methods exist todetermine unambiguously the distribution of elements withinthe solid phase (see above). Nevertheless, this extraction procedureprovides an operationally defined soil-phase fractionation thatis convenient for comparison of treatments. The chemical formswere labeled according to the targeted geochemical compartmentsduring each extraction step: water soluble (WAT), exchangeable(EXCH), bound to Mn oxides (MNOX), bound to amorphous or poorlycrystallized Fe oxides (FEOX1) or to well crystallized Fe oxides(FEOX2), associated with organics (OM), residual (RES).

Each element in the different fractions was expressed in microgramsextracted per gram of soil and in total amount percentage ofthe metal extracted after the seven steps (Me₇). Elements wereanalyzed by ICP-AES. Calibration was done with standard solutionsanalyzed at the beginning of series and after each 15 sampleseries.

Transmission Electron Microscopy Observations and Microanalysis
Air-dried samples were suspended in ethanol under ultrasonication.A drop of suspension was then evaporated on a carbon-coatedcopper grid and the preparation was observed with a TransmissionElectron Microscope (TEM Philips CM 20, Philips, Eindhoven,the Netherlands) at an accelerated voltage of 200 kV. Microanalysisof selected particles were carried out using an EDAX energydispersive X-ray spectrometer (EDXS) associated to the TEM.

Statistical Analysis
The effects of microbial weathering treatments on the differentfractions were evaluated with an analysis of variance (ANOVA)that allows comparison of samples before and after incubation.The comparisons of means were made with the Fisher's PLSD test(least significant difference) (p < 0.05) using Statview4.02 (Abacus Concepts, Inc., Berkeley, CA).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Soil Characteristics
Total element analysis showed a very high content of Fe andrelatively high contents of Mn, Cr, Ni, and Co in the soil sample(Table 2). Iron was mainly present as goethite and Mn as a nonidentifiedmixed-layers Mn oxide (Becquer et al., 2001a; Quantin et al., 2002).Dithionite citrate bicarbonate (DCB) and hydroxylamineextractions as well as TEM observations and EDXS analysis showedthat Ni and Cr were mainly associated with goethite whereasCo and <1% of Ni were associated to Mn oxides (Becquer et al., 2001a;Quantin et al., 2002). The Si content was very lowin this soil sample and mainly present as talc mineral withtraces of chlorite and quartz. The SOM content reached 5% andthe C/N ratio was close to 22.

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Table 2. Main characteristics of the soil sample.

Total Microbial Activity
In abiotic treatments, CO₂ production was negligible and onlybecause of chemical degassing (Fig. 1) . The values were thesame in all the abiotic treatments. In contrast, in biotic treatments,C mineralization was significant and reached 13.8, 16.8, and18.9 g C-CO₂ kg^-1 of the total C content for SOM, GLU, and CELtreatments, respectively, after 140-d incubation (Fig. 1). Kineticsof mineralization were quite different for the three treatments.In the SOM treatment, organic matter mineralization increasedslowly with time and reached a maximum rate of 0.107 g C-CO₂kg^-1 C d^-1 (Quantin et al., 2001). In the GLU treatment, C mineralizationincreased very fast after a 2-d lag-period. Mineralization ratewas 0.714 g C-CO₂ kg^-1 C d^-1 during 22 d and then decreasedto zero after 75 d. For the CEL treatment, the CO₂ productionwas low and similar to that of the SOM treatment during thefirst 3 wk. After this period, C mineralization increased from0.064 to 0.164 g C-CO₂ kg^-1 C d^-1. At the end of incubation,the cumulative quantity of mineralized C became higher thanin the GLU treatment (Fig. 1).

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Fig. 1. Carbon mineralization in experiments with (GLU and CEL) and without (SOM) organic addition under biotic conditions and in controls.

Metal Solubilization
In abiotic treatments, metal solubilization was low especiallyfor Fe and Mn (Fig. 2 and Table 3). For Co and Ni, <1.5and 0.1% of total metals was solubilized, respectively, andthis was ascribed only to exchange with the added sodium thimerosal(Quantin et al., 2001).

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Fig. 2. Metal solubilization in GLU, CEL, and SOM treatments under biotic and abiotic anoxic conditions.

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Table 3. Percentage of maximal solubilization of Fe, Mn, Co, and Ni in soil organic matter (SOM), glucose treatment (GLU), and shredded cellulose treatment (CEL) biotic and abiotic treatments and percentage of metal solubilization at 140 d of incubation.

Iron and Manganese
In the SOM treatment, maximum solubilization of Fe was closeto 0.2% of Fe_t whereas solubilized Mn reached 17% of Mn_t (Table 3).A decrease of soluble Mn was observed at the end of theexperiment corresponding to sorption phenomena (Fig. 2). Intreatments where microbial activity was greatly stimulated byhydrocarbon input, Fe and Mn release reached 0.75% of Fe_t and32% and 26% of Mn_t for GLU and CEL, respectively. The solubilizationkinetics were quite different between treatment as metal solubilizationstarted earlier in the GLU treatment than in CEL (Fig. 2).

At Day 140, the amounts of dissolved metals decreased markedlyfor Mn and slightly for Fe, and the metals were assumed to besorbed onto the solid phase either adsorbed or precipitated.The decrease of dissolved metal contents at the end of the experimentshows that, at this period, metal solubilization becomes slowerthan the sorption processes (Fig. 2).

Cobalt, Nickel, and Chromium
Cobalt and Ni release was low for all treatments (Fig. 2 andTable 3). However, in the GLU treatment, Co solubilization reached7% of Co_t after 24-d incubation (Quantin et al., 2001) afterwhich the Co content in solution decreased. In the CEL treatment,Co release reached 2.5% of Co_t, whereas in the SOM treatmentit was only 1.2%. For Ni, a similar tendency was observed. Themaximum release (0.48% of Ni_t) occurred in the GLU treatmentafter 14 d whereas in the other treatments it was not significantlydifferent from abiotic controls.

Chromium was never detected in solution for any of the treatments(detection limit: 1 mg L^-1).

Partitioning of Metals in the Soil
The cumulative amounts of elements recovered during the seven-stepSSE procedure were up to 85% of that obtained by a single-steptotal analysis.

Only small changes in metal distribution were observed in controlswhere bacterial activity was inhibited by thimerosal (data notshown). In these abiotic treatments, water soluble and exchangeablemetals increased slightly during incubation because of the effectof sodium thimerosal, whereas other compartments remained constant.So, in the results below, only the distribution of the metalsin the geochemical compartments at the end of the biotic treatmentswere presented and discussed in comparison to the initial distribution.

Iron
Iron was intimately associated with the reducible fraction correspondingto well-crystallized Fe oxides (40.8% of Fe₇, Table 4). Ironquantified in the residual fraction (53.5%) was overestimatedbecause the DCB extraction was not complete as indicated bythe colored residue suggesting that some goethite was not dissolvedby the conventional extraction of crystallized Fe oxides adoptedin this experiment. However, more than 95% of Fe can be extractedby DCB during a 772-h extraction at room temperature (Becquer et al., 2001b).After incubation, Fe associated with FEOX1 (9100mg kg^-1 soil, i.e., 2.7% of Fe₇, initially) increased in theGLU treatment (30567 mg kg^-1 soil) and to a lesser extent inCEL (15590 mg kg^-1 soil), where microbial activity was high.Although this compartment remained small compared with FEOX2and RES, these results show that a part of Fe oxides is renderedamorphous during microbial weathering, especially when it isstimulated by the addition of a biodegradable organic mattersuch as glucose or cellulose. In these treatments, subsequentsorption and coprecipitation processes likely occurred and contributedto the increase of the FEOX1 compartment. Transmisssion electronmicroscope observations showed the formation of an amorphousgel of Fe-Si (less electron dense part of the picture, Fig. 3a)in the GLU treatment, where a strong bacterial activityoccurred. Microanalysis revealed that this amorphous Fe-Si gelcontained Mn, Ni and Cr (Fig. 3b). A significant increase ofFe content was also observed in the OM compartment regardlessof treatments.

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Table 4. Concentrations of Fe, Mn, Ni, Co, and Cr in the solid compartments of the initial and incubated soils.

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Fig. 3. Transmission electron microscopy (TEM) micrograph of amorphous Fe-Si gel in GLU treatment (a) and EDX spectrum of the gel (b).

Manganese
In the initial sample, Mn was mainly associated with the MNOXfraction solubilized by hydroxylamine hydrochloride (2330 mgkg^-1 soil, i.e., 52% of Mn₇, Table 4), with 12 and 18% of Mnassociated with FEOX1 and FEOX2, respectively. After batch incubation,a major redistribution of Mn in the different fractions wasobserved. The quantity of Mn in MNOX decreased significantlyirrespective of treatment from 52 to 19.5, 15, and 12.5% (ofMn₇) for SOM, CEL, and GLU, respectively. In contrast, the amountof Mn increased significantly during incubation in three othercompartments: EXCH, FEOX1, and OM. Manganese associated withthe exchangeable fraction increased in CEL and SOM treatmentsfrom 3% (146 mg kg^-1 soil) to 15 and 14%, respectively. Theincreased quantity of Mn in FEOX1 was particularly high forboth GLU (2073 mg kg^-1 soil, i.e., 43%) and CEL (1154 mg kg^-1soil, i.e., 28%) treatments.

Nickel
In the initial sample, Ni was mainly recovered in the FEOX2(3170 mg kg^-1 soil, i.e., 40% Ni₇) and RES (4486 mg kg^-1 soil,i.e., 57% Ni₇) compartments (Table 4). In general, we observedthat the most labile fractions of Ni (water soluble, exchangeable,Mn oxide, and poorly crystallized Fe oxide bound) increasedin all the biotic treatments by a factor of two (SOM treatment)to four (GLU treatment) at the end of incubation. A significantincrease in the OM compartment was observed for the three treatments.Nevertheless, these fractions were quantitatively minor comparedwith FEOX2 and RES, except for the FEOX1 fraction that, forexample, increased from 1.3 to 5.7% of Ni in the GLU treatment.

Cobalt
Initially, Co was mainly extracted by hydroxylamine (337 mgkg^-1 soil, i.e., 47% Co₇) and thus appeared to be associatedwith Mn oxides. Furthermore, 32% of the Co was associated withFEOX1 and FEOX2, and 20.3% with RES, and <1% was exchangeableby KCl.

After incubation, a major redistribution of Co occurred in thesolid phase, as observed for Mn. The quantity of Co associatedto the Mn oxides decreased significantly in all treatments,whereas Co increased in EXCH, FEOX1, and FEOX2. ExchangeableCo was particularly high for the GLU and CEL treatments, wheremicrobial activity was high.

Chromium
For Cr, 85 to 95% of Cr_t were recovered by the SSE procedure.Initially, 6320 mg kg^-1 soil, that is 67% of Cr₇ were presentin the RES fraction. Becquer et al. (2001a) showed that Cr canbe incorporated partly in spinel minerals such as chromite.Given the resistance of this mineral, we can consider that theblack residue observed on filters even after diacid attack wasmainly composed by chromite. Thirty percent of Cr₇ were recoveredas FEOX2 and only 2 and 1.2% were associated with OM and FEOX1,respectively. Nevertheless, Becquer et al. (2001a) showed thatafter long time DCB extraction Cr appeared preferably associatedwith crystallized Fe oxides (substituted goethite). The relativelylower content extracted here may be because of an incompleteoxide solubilization during the extraction. Besides Cr is knownto stabilize the oxide structure (Schwertmann, 1991; Bousserrhine et al., 1999),which may explain the incomplete solubilizationof Fe oxide during DCB extraction.

After 140 d of incubation, Cr associated with FEOX1 increasedsignificantly in CEL and GLU treatments from 1.2 to 3.7 and1.8% of extracted Cr, respectively. Exchangeable Cr which initiallyrepresented 0.035 mg kg^-1 soil increased significantly in alltreatments.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

The present experimental approach simulated the interactionsbetween minerals, organics and microbes occurring in soil. Theresults underline that, under anaerobic conditions, bacterialdegradation of organic matter and bacterial Fe and Mn reductioncan drastically influence the mobility of metals and their partitioninginto different compartments of the solid phase.

Soil organic matter as a C source supported bacterial activitythat increased with the addition of easily biodegradable compounds(glucose or cellulose). Thus C mineralization increased, andthe kinetics of CO₂ production varied with the nature of theorganic substrate and the involvement of different types ofmicrobial communities, as described by Quantin et al. (2001).

The oxidation of organic matter leads to the production of electrons,and is as a consequence associated to the reduction processesof electron acceptors. Manganese and Fe oxides are among themain electron acceptors that allow bacterial activity in soilsunder anaerobic conditions, and Mn and Fe solubilization isa direct result of anaerobic bacterial activity (Quantin et al., 2001).Solubilization is greatly stimulated by organicmatter inputs, as observed in the experiments where Mn and Ferelease reached quite high levels. The bacterial reduction ofMn and Fe also resulted in the solubilization of Co and Ni associatedto oxides. Fe and Mn oxides are known to be the main scavengersof these trace metals in this type of soil (Schwertmann and Latham, 1986;Becquer et al., 2001b), and the association ofCo and Ni with Fe and Mn oxides was verified by selective SSE.

A reduced content of Mn, Ni, and Co in solution and, to a lesserextent, Fe was observed at the end of experiment. This probablycorresponded to sorption and coprecipitation processes. Selectivesequential extractions are commonly used to determine elementpartitioning in soils (Shuman, 1985; Schramel et al., 2000;Han et al., 2001), in lakes, river, or synthetic sediments (Tessier et al., 1979;Kheboian and Bauer, 1987; Chartier et al., 2001),as well as in sewage sludges and urban wastes (McGrath and Cegarra, 1992;Prudent et al., 1996). Such extractions were used in thisstudy to describe the evolution of the metal distribution amongsoil compartments. Chemical reagents are expected to removeelements from well-defined geochemical compartments, and eachextraction refers to the target fraction (e.g., Mn oxides forhydroxylamine hydrochloride). The characterization of metalsthrough SSE has been criticized for the lack of specificityof certain reagents, for the risk of element redistributionduring the procedure, and for the change in redox status ofreleased elements (Sheppard and Stephenson, 1995; Cornu and Clozel, 2000;Han et al., 2001). Some authors reported a redistributionof metals (particularly Mn and Fe) and a change in redox statusafter drying and rewetting (Bartlett and James, 1980; Bartlett and James, 1993;Sparks, 1996). These modifications seem toaffect the most labile fractions (i.e., water soluble and exchangeableones). Either an increase (Bartlett and James, 1980) or a decrease(Gambrell, 1996; Loeppert and Inskeep, 1996) in metal contentof these fractions have been reported. In our experimental conditions,drying may lead to underestimate the water soluble and alsoto a lesser extent the exchangeable elements, particularly Mnand Fe. Still such SSE have been used to describe the partitioningof trace metals in paddy soils in relation to Zn nutrition (Mandal and Mandal, 1986),in arid soils after repeated wetting-dryingcycles (Han et al., 2001) and in sediments after apatite addition(Arey et al., 1999) or oxygenation (La Force et al., 1999).

The partitioning of metals described by SSE showed two typesof behaviors corresponding to the association of two distinctgroups of metals with the main mineral phases of the soil. Firstly,Mn and Co, associated in Mn oxides at the start of the experiment,behaved similarly and disappeared to a large extent in thismineral compartment, whereas their concentration in the amorphousand poorly crystallized Fe oxide compartment increased correspondingly,as well as in the exchangeable fraction. A similar increasein FEOX2 (reducible Fe oxide compartment) was also noted forCo. Secondly, Fe, Ni, and Cr, that were mainly associated withFEOX2 at the beginning, increased in the amorphous and poorlycrystallized Fe oxide compartment and, to a lesser extent, inthe exchangeable compartment. The bacterial reduction of Mnand Fe oxides leads to a major transformation of mineral phasesand a redistribution of metals through the solid phase. Soilincubation yields a strong decrease of the Mn oxides and anincrease of amorphous and poorly ordered Fe oxides, as wellas exchangeable compartments. The increase in the amorphousand poorly ordered Fe oxide compartment was greater than thedecrease of the Fe content in solution, showing that a realamorphization of Fe oxides occurred. Transmission electron microscopeobservations and EDXS analysis also confirmed the formationof an amorphous Fe oxide phase associated with the metals.

Amorphous Fe oxides are strong sorbents because of their highspecific surface area (Cornell and Schwertmann, 1996) and theformation of substituted metal Fe oxides. During microbial weathering,amorphous Fe oxides can also act as a sink for metals releasedin solution. After microbial weathering, a large proportionof Mn, Ni, and Co occurs in the amorphous Fe oxide fraction.The net increase with time of this freshly formed mineral phasewith a high sorbing capacity, simultaneously with the decreaseof the reduction process and metal solubilization, resultedin increased quantities of metals bound to this fraction. Formationof this mineral phase explains the decrease of metal concentrationsin solution as suggested by Soon (1994), who observed that Znreleased during soil weathering became preferentially associatedwith amorphous Fe oxides, whereas the crystalline oxides werestable. Thus different Fe compounds appear to control the behaviorof other metals under experimental conditions as Hazra et al. (1987)observed for Zn availability to rice. Mandal and Mandal (1986)also reported that hydrous Fe oxides controlled Zn availabilityto plant under flooded conditions. Other reports have attributeda smaller or negligible role of Fe oxides in plant mineral nutritionunder aerobic conditions (Soon, 1994) because of the diffusionof metals like Zn into oxide lattices which renders them unavailable(Brümmer et al., 1988). Further, during the bacterial reductionprocesses, pH increases (Quantin et al., 2001) because of theFe³⁺ to Fe²⁺ reduction and leads to a decrease in metal solubilitythat also favored precipitation of metal hydroxides and theiradsorption on the surfaces of freshly formed amorphous and poorlycrystallized Fe oxides. During the drought periods, the crystallizationof amorphous Fe oxides and the subsequent stabilization andincorporation of the metals into the mineral lattices (Han et al., 2001)could lower the availability of metals. Microbialweathering led to the increase of some easily available phases.Despite some bias discussed above, the water soluble and theexchangeable fractions of metals increased significantly. Organicmatter also appears to play an important role in the dynamicsof Fe, Mn, and Ni as the fraction of metals associated withorganic matter, either specifically adsorbed or complexed, alsoincreased. Moreover, this fraction is probably underestimatedbecause a part of metals associated to this fraction can beremoved before the organic matter step of the SSE procedure.These different compartments (water soluble, exchangeable andorganic) are the sources of easily bioavailable metals and theseelements could also be leached out and then removed from thesoil profile.

CONCLUSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

Bacterial weathering processes under anaerobic conditions, involvingreduction and dissolution of major (Fe, Mn) and trace elements(Co, Ni) from oxides, brings about a significant modificationof metal distribution into the geochemical compartments of soil.An increase in the concentration of metals in the most labilecompartments is readily observed during anoxic incubation. Anincrease may be observed in amorphous or poorly crystallizedFe oxides that are highly dependent on soil properties and environmentalfactors such as pH, E_H, and microbial activity. The well-crystallizedFe oxides as well as the residual fraction are quite stablemetal compartments. Metals in these two latter compartmentsmay be considered as the least labile or least bioavailablemetals.

Soil moisture and available organic C both control bacterialactivity including bacterial reduction directly affecting metalredistribution. Soils experiencing both saturation and wetting-dryingregimes are very reactive, then the metals they contain canbe redistributed into more or less labile fractions. The Ferralsolused in this study constitutes a major soil type in New Caledonia.Thus it is likely to experience major fluctuations in availabilityof metals. During drought periods, low availability will resultfrom the crystallization of amorphous Fe oxides and the subsequentstabilization and incorporation of the metals into the minerallattices. Upon water saturation, metal availability will againincrease and be prone to plant uptake during the subsequentgrowth season.

ACKNOWLEDGMENTS

This work was supported by a grant awarded to C. Quantin bythe French Ministry of National Education, Research and Technologyand by the French Ministry of Environment (MATE). We thank Dr.E.J. Joner and Pr. J. Gentry for proof-reading the English manuscript.

Received for publication August 2, 2001.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
CONCLUSION
REFERENCES

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Bousserrhine, N., U.G. Gasser, E. Jeanroy, and J. Berthelin. 1999. Bacterial and chemical reductive dissolution of Mn-, Co-, Cr- and Al-substituted goethite. Geomicrobiol. J. 16:245–258.

Brümmer, G.W., J. Gerth, and K.G. Tiller. 1988. Reaction kinetics of the adsorption and desorption of nickel, zinc and cadmium by goethite. I. Adsorption and diffusion of metals. J. Soil Sci. 39:37–42.

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