Nature of Clay-Humic Complexes in an Agricultural Soil: I. Chemical, Biochemical, and Spectroscopic Analyses

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DIVISION S-2 - SOIL CHEMISTRY

Nature of Clay-Humic Complexes in an Agricultural Soil

I. Chemical, Biochemical, and Spectroscopic Analyses

D. A. Laird^*^,a, D. A. Martens^b and W. L. Kingery^c

^a USDA-ARS, National Soil Tilth Lab., 2150 Pammel Drive, Ames, IA 50011
^b USDA-ARS, Southwest Watershed Research Center, 2000 E. Allen Road, Tucson, AZ 85719-1596
^c Dep. of Plant and Soil Sciences, Mississippi State Univ., P.O. Box 9555, Mississippi State, MS 39762

* Corresponding author (laird{at}nstl.gov)

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

Soil management systems that encourage the formation and stabilizationof recalcitrant clay–humic complexes will have the greatestlong-term impact on C sequestration and soil quality. The objectiveof this study was to determine the relationship between thechemical, biochemical, and spectroscopic characteristics ofhumic substances and clay mineralogy. Clay–humic complexeswere separated from the Ap horizon of a Webster soil (fine-loamy,mixed, superactive Typic Endoaquoll) by an invasive sonication–centrifugationtechnique. The samples were analyzed for mineralogy by XRD (x-raydiffraction), chemical composition by inductively coupled plasma-atomicemission spectorscopy (ICP-AES), C and N by thermal combustion,C chemistry by solid state ¹³C magic angle spinning-nuclearmagnetic resonance spectroscopy (MAS-NMR) and both gas chromatography(GC) and high performance liquid chromatography (HPLC) analysesof extractable organic compounds. The coarse, medium, and fineclay fractions are dominated by quartz, a low-charged interstratifiedphase, and smectite, respectively. Extractable organic compounds,30 to 52% of the total C, are dominated by basic amino acidsand polyunsaturated fatty acids. Less than 3% of the extractableC is monosaccharides and amino sugars and only trace levelsof phenolic acids were found. The C/N ratios of humic substancesassociated with the coarse, medium, and fine clay fractionsare 17, 10, and 10, respectively. The coarse clay fraction hasstronger carboxyl and O-alkyl ¹³C-NMR peaks and lower levelsof extractable amino acids, fatty acids, monosaccharides, andamino sugars than humics associated with the fine clay fraction.The results indicate that the biochemistry of the clay–humiccomplexes differs substantially from that of whole soils andthat soil clay mineralogy strongly influences humification.

Abbreviations: CEC, cation-exchange capacity • FAME, methylated fatty acids • GC, gas chromatography • HPLC, high performance liquid chromatography • ICP-AES, inductively coupled plasma-atomic emission spectroscopy • MAS-NMR, magic angle spinning-nuclear magnetic resonance spectroscopy • OC, organic C • OM, organic matter • XRD, x-ray diffraction

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

AGRICULTURAL SOILS have the potential to make a significantcontribution towards reducing net emissions of greenhouse gases(CO₂ and CH₄) to the atmosphere through increased C sequestrationin soil organic matter (OM). In a recent analysis, Bruce et al. (1999)estimated that with prudent management about 1.1x 10¹⁵ g of C could be sequestered in USA and Canadian soilsover the next two decades, and that C sequestration in agriculturalsoils could contribute 15% of the net reductions in C emissionsneeded to bring the USA and Canada in compliance with the KyotoProtocols (United Nations, 1997). Increasing soil OM has theadded benefit of improving soil quality and thereby enhancingthe long-term sustainability of agriculture. However, developmentof management systems that optimize C sequestration in agriculturalsoils will require increased understanding of the biogeochemicalprocesses that influence the complex cycling of organic C (OC)in soils.

The biogeochemical cycling of OC in soils is divided into twogeneral processes, (i) microbially mediated decomposition ofbiological materials to either volatile gases (CO₂ and CH₄)or humic monomers; and (ii) abiotic polymerization of humicmonomers to form humic substances (Stevenson, 1994) (Note, inthis paper the term humic substances refers to the productsof secondary synthesis and is distinguished from the terms humicacid and fulvic acid which refer to materials obtained by aparticular extraction procedure). Soil clay minerals are believedto serve three critical functions in the formation and stabilizationof humic substances: First, humic monomers are adsorbed on claysurfaces where they accumulate over time. Second, clay mineralsare believed to catalyze the abiotic polymerization of the adsorbedhumic monomers. And third, adsorbed humic substances may bephysically sequestered by clay minerals and hence unavailableto soil microorganisms.

The ability of clay minerals to adsorb and catalyze polymerizationof synthetic humic monomers has been demonstrated in numerouslaboratory studies. For example, nontronite, montmorillonite,illite, and kaolinite have all been shown to adsorb and significantlyenhance the polymerization of polyphenols and the copolymerizationof amino acids and polyphenols (Wang and Huang, 1989; Wang, 1991;Bosetto et al., 1997). Clay mineralogy and the type ofinorganic cations adsorbed on the clay significantly effectboth the rate and the products of the polymerization reactions.

Considerable evidence indicates that OM associated with finesoil clay particle-size fractions is more aliphatic, has relativelylower C/N ratios, younger radiocarbon ages, and greater labilityduring laboratory incubations compared with OM associated withcoarse clay particle-size fractions (Arshad and Lowe, 1966;Ladd et al., 1977; Anderson et al., 1981; Tiessen and Stewart, 1983;Catroux and Schnitzer, 1987). However, the cause of thesedifferences is poorly understood and evidence relating the observeddifferences to clay mineralogy is often equivocal. Common tomany studies are fractionation schemes that seek to minimizedisruption energy, in an attempt to isolate ecologically significantfractions. Such schemes, however, typically fail to isolateclay-organic complexes of mineralogical significance. For example,Catroux and Schnitzer (1987) used a mild ultrasonic techniqueto isolate particle-size fractions from a surface horizon sampleof an Ontario Aquoll. Mechanical analysis revealed that thesample contained 22% clay, 45% silt, and 35% sand, while recoveriesfollowing the mild ultrasonic dispersion were 15% clay, 55%silt, and 30% sand. Furthermore, only 1% of the mass was recoveredas fine clay (<0.2 µm), whereas from a mineralogicalperspective such soils are dominated by fine clays. As furtherexample, Arshad and Lowe (1966) characterized OM associatedwith coarse-, medium-, fine-, and very fine-size fractions ofa Bnt horizon from a soil dominated by smectitic clays. Theyfound more OM associated with the coarse clay fraction whichwas predominantly smectitic but also contained kaolinite. Froma mineralogical perspective, smectites are a component of thefine clay fraction and only present in coarse clays as a contaminantdue to incomplete dispersion.

The goal of our research is to develop an understanding of theinfluence of clay mineralogy on the formation and stabilizationof humic substances in soils. The specific objective of thisstudy was to determine the relationship between mineralogy andthe chemical, biochemical, and spectroscopic characteristicsof humic substances associated with mineralogically significantclay fractions separated from a typical agricultural soil.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

The soil sample used in this study was collected from an agriculturalfield located on the University of Minnesota Southern AgriculturalExperiment Station, near Waseca, MN. The sample was collectedfrom the Ap horizon (0–15 cm) of a Webster pedon. Thesoil was mechanically dispersed in distilled water without chemicalpretreatments and a bulk sample of the soil clay (<2 µmparticle-size fraction) was separated by sedimentation and airdried as described previously (Laird et al., 1991a). The soilclay sample has been used in several previous investigations,and detailed analyses of the clay mineralogy (Laird et al., 1991a;Laird and Nater, 1993) and reactions between atrazineand various soil clay fractions (Laird et al., 1994) have beenreported.

A Na-saturated clay suspension was prepared by shaking 60 gof soil clay with 2 L of 2 M NaCl. After the clay settled (24h), the supernatant was discarded and then the sample was dispersedby shaking in 2 L of deionized water. Approximately 25% of theclay suspension was retained as the whole clay (<2.0 µm)sample. The remaining 75% of the suspension was fractionatedusing a sonication-centrifugation-decantation technique to separatethe coarse (0.2–2.0 µm), medium (0.02–0.2µm), and fine (<0.02 µm) particle-size fractions.To do so, 33 mL of the suspension (1 g clay) were transferredto 50 mL centrifuge tubes and subjected to seven sequentialfractionation steps. For each fractionation step, the sampleswere diluted to 33 mL with distilled water, dispersed by bothmechanical agitation and sonication (30 s at 40 W), centrifugedfor 20 min at the appropriate speed (Jackson, 1985), and decanted.The first five fractionation steps separated the <0.02 and0.02- to 2.0-µm fractions, and the last two fractionationsteps separated the 0.02- to 0.2- and 0.2- to 2.0-µm fractions.

Clay in the suspensions was flocculated by adding excess NaCl,allowed to settle, and the solution decanted. One portion ofeach size fraction was retained as the untreated sample, andanother portion of each size fraction was treated with 30% (v/v)H₂O₂ for removal of OM (Kunze and Dixon, 1986). All sampleswere washed four times with 0.5 M CaCl₂, dialyzed against distilledwater and freeze dried.

Total C and N were determined by dry combustion using a CarloErba¹ NA1500 NSC elemental analyzer (Haake Buchler Instruments,Paterson, NJ). Elemental analysis (Al, Ca, Fe, K, Mg, Mn, Si,Ti, and Zn) of the clay samples was performed with an ICP-AESusing the suspension nebulization technique (Laird et al., 1991b).Cation-exchange capacities (CEC) were determined using the ICP-AESanalysis of Ca, the index cation, relative to the sample ovendried weights. The mineralogy of the samples was determinedby x-ray diffraction (XRD). Portions (100 mg) of the Ca-saturatedsamples were slurried in 95% (v/v) ethanol, oriented on glassslides by the paste method, air dried, and analyzed between2 and 30° 2 ${Theta}$ using Cu K ${alpha}$ radiation. Percentages of mineralphases are based on elemental mass balance using the known chemistryof 2:1 phyllosilicates in the Webster soil clay (Laird et al., 1991a).

The chemical nature of OM associated with the untreated sampleswas determined using solid state ¹³C-NMR. The ¹³C-NMR spectrawere obtained using a Bruker AMX-300 spectrometer (Bruker Instruments,Inc., Brillerica, MA) operating at a resonance frequency of75.4 MHZ. Data were collected with cross polarization, usingbilevel decoupling, together with magic angle spinning. Experimentaldata acquisition parameters included 1 ms contact times and4 s recycle delays while samples were spun at 7 kHz. A totalof 24000 scans were used to produce each spectrum.

Acid extractable monosaccharides, amino acids, and amino sugarsin the untreated samples were measured by ion chromatographywith pulsed amperometric detection (Martens and Frankenberger, 1990,1992). Monosaccharides were extracted by refluxing 50mg of clay with 1 M H₂SO₄ at 80°C for 16 h, then the samplewas titrated to pH 5 with 5 M KOH, centrifuged, and an aliquotof the supernatant was diluted for analysis. Amino acids andamino sugars were extracted by autoclaving 50 mg of clay for16 h with 4 M methanesulfonic acid (2 mg tryptamine mL^-1), thesample was titrated to pH 5 with 5 M KOH, centrifuged, and analiquot of the supernatant was diluted for analysis. The extractswere analyzed using a Dionex DX-500 (Dionex Corp., Sunnyvale,CA) ion chromatograph equipped with a CarboPac PA10 (2-mm i.d.)column for monosaccharide analysis and an AminoPac PA10 (2-mmi.d.) column for amino acid and amino sugar analysis. Separationswere achieved with a NaOH gradient (5–80 mM) for monosaccharidesand a NaOH-Na acetate gradient (30–80 mM NaOH; 0–500mM Na acetate) for amino acids and amino sugars.

Phenolic acids were extracted from 50-mg clay samples with 5mL of 4 M NaOH heated in Teflon microwave digestion bombs to160°C in a CEM MDS-2000 microwave digester (CEM Corp., Matthews,NC) operated at 650 W (Provan et al., 1994). After cooling,the supernatant and solids were separated by centrifugation-decantation;then the solids were washed with water and the supernatantscombined. The supernatant sample was titrated to <pH 2.0with 4 M HCl, diluted to 14 mL, centrifuged to remove the formedprecipitate, and an aliquot passed through a Varian (VarianAssoc., Harbor City, CA) Bond Elut PPL solid phase extractiontube. The tubes were dried under a stream of air and the phenoliccompounds were eluted with 1 mL of ethyl acetate into GC autosamplervials. The phenolic compounds (1 µL; 10:1 split) werethen analyzed with a Hewlett-Packard 6890 gas chromatograph(Hewlett Packard Co., Palo Alto, CA) equipped with a HP-5 (5%cross-linked phenylmethyl siloxane) capillary column (30-m length,0.32-mm column i.d., 0.25-µm film thickness) and detectedwith a flame ionization detector. The following conditions wereemployed for phenolic acid separation: injector temperature,230°C; temperature ramp, 70°C for 2 min then rampedto 250°C at 10°C min^-1; detector temperature, 250°C.

Fatty acids were extracted from the clay samples (100 mg) with10 mL of a monophasic mixture of methanol, chloroform, citratebuffer (2:1:0.8, v/v/v) for 2.5 h at 80°C (Frostegard et al., 1993).The solution and solids were separated by centrifugationand the supernatants were placed into glass test tubes withTeflon lined caps. The samples were split into two phases byadding chloroform and buffer; then the citrate-methanol phasewas removed and chloroform phase dried under a stream of air.The sample was methylated by addition of 1 mL methanol, chloroform,concentrated HCl (10:1:1, v/v/v), and the mixture was heatedovernight at 60°C (Zelles and Bai, 1993). The methylatedfatty acids (FAMEs) formed were extracted by addition of 0.5mL chloroform and 4 mL water. The chloroform phase was thenremoved after centrifugation for analysis with a Hewlett-Packard6890 GC (Hewlett Packard Co., Palo Alto, CA) equipped with aHP-5 (5% cross-linked phenylmethyl siloxane) capillary column(30-m length, 0.32-mm column i.d., 0.25-µm film thickness)and detected with a flame ionization detector.

The identities of FAME and phenolic compounds were confirmedwith a Hewlett-Packard 1800A GCD (Hewlett Packard Co., PaloAlto, CA) gas chromatograph equipped with a HP-Ultra 1 capillarycolumn (25-m length, 0.2-mm column i.d., 0.33-µm filmthickness) and a mass selective detector operated in the fullscan (10–450 m/z) electron impact mode (70 eV, sourcetemp. 170°C). The following conditions were employed forphenolic acid separation: 1-µL splitless injection, injectortemperature of 250°C, initial column temperature of 70°Cramped to 250°C at 10°C min^-1, and detector temperatureof 280°C. The temperature ramp used to separate the FAMEswas 70°C (2 min) then ramped to 140°C (10°C min^-1),to 180°C (3°C min^-1), and to 275°C (7°C min^-1)for 10 min. The mass spectra of standards and unknowns werecompared with a NIST spectrum library.

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

The clay mineralogy of the Webster soil has been extensivelystudied (Laird et al., 1991a; Laird and Nater, 1993). Coarse-clayseparates are dominated by quartz with lesser amounts of 10Å-illite,kaolinite, and feldspars. Fine-clay separates contain smectiteand a low-charged interstratified phase. The smectite is a high-Femontmorillonite with a moderate layer charge [0.482 (-) performula unit] and 47% tetrahedral charge. The low-charged interstratifiedphase consists of randomly interstratified 10 and 15 Å2:1 phyllosilicate layers with a layer charge of 0.473 e performula unit and 87% tetrahedral charge (Laird et al., 1991a).Although, the low-charged interstratified phase cannot be classifiedusing current nomenclature guidelines (Bailey et al., 1982),it has unofficially been referred to as "protoillite" (Laird and Dowdy, 1994)and that convention will be followed hereafterin the present manuscript.

X-ray diffraction patterns for H₂O₂-treated samples of the whole-,coarse-, medium-, and fine-fractions of the Webster soil clayare presented in Fig. 1 , and chemical analysis of the H₂O₂-treatedsamples are given in Table 1. The analyses revealed significantlydifferent mineralogies for the coarse, medium, and fine clayfractions. The coarse clay fraction is dominated by quartz,but also contains kaolinite, protoillite, 10Å-illite,and feldspars. Because of the large number of mineral phasespresent, quantification of the clay mineralogy for the coarseclay fraction was not attempted. The medium clay fraction contains70% (w/w) protoillite, 25% (w/w) smectite, and 5% (w/w) kaolinite;and the fine clay fraction contains 82% (w/w) smectite and 18%(w/w) protoillite.

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Fig. 1. X-ray diffraction (XRD) patterns of H₂O₂-treated clay fractions from the Webster soil. The samples were Ca-saturated, oriented on glass slides, air dried, and analyzed using Cu K ${alpha}$ radiation.

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Table 1. Chemical composition of the H₂O₂-treated whole-, coarse-, medium-, and fine-clay fractions isolated from the Webster soil.

Chemical analyses of OM in the untreated soil clay fractionsare presented in Table 2. No effervescence was observed whenthe original soil sample was treated with acid, no carbonateminerals were identified in the XRD analysis, and the pH ofthe various Ca-saturated soil clay fractions in distilled wateris 5.0 ± 0.1; hence, all of the C in the soil clay fractionsis assumed to be organic. Total C determined by thermal combustionranges from 69.8 g C kg ^-1 clay in the coarse clay fractionto 51.7 g C kg^-1 clay in the fine clay fraction. Total N rangesfrom 6.4 g N kg ^-1 clay in the medium clay fraction to 4.1 gN kg^-1 clay in the coarse clay fraction. The coarse clay hasa C/N ratio of 17 while the medium and fine clay fractions haveC/N ratios of 10. The CEC of the clay–humic complexesrange from 0.65 mol(+) kg^-1 for the coarse clay to 1.02 mol(+)kg^-1 for the fine clay. The CEC's decreased following the H₂O₂treatment, reflecting the contribution of the humic substancesto the CEC of the clay–humic complexes. The largest decreasein CEC was for the coarse clay fraction [0.33 mol(+) kg^-1] andthe smallest decrease in CEC was for the fine clay fraction[0.11 mol(+) kg^-1].

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Table 2. Chemical properties of soil clay fractions from the Webster soil. Standard deviations are given in parentheses. Data originally presented in Laird et al. (1994).

Results of the biochemical analyses of the various soil-clayfractions are presented in Table 3. The sum of extractable Cranged from 19.9 g C kg^-1 clay for the whole clay to 26.9 gC kg^-1 clay for the fine clay. The sum of extractable C forthe coarse and fine clay fractions account for 29.9 and 52.0%,respectively, of the total C as determined by thermal combustion.Most of the extractable C was in unsaturated C18 fatty acids(12.2–28.3%) and amino acids (9.3–17.1%). Less than3% of the C was identified as monosaccharides and amino sugarsand <0.3% was identified as phenolic acids. The N in aminoacids and amino sugars accounts for nearly all (82–103%)of the N in the samples as determined by thermal combustion.Arginine, by far the most abundant amino acid, accounts for50 to 66% of the total N in the soil clay extracts. Lysine isthe second most abundant amino acid and contributes 3 to 8%of the total N in the samples.

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Table 3. Biochemistry of organic compounds extracted from the Webster clay fractions.

Solid-state ¹³C-NMR analysis was used to further evaluate thechemical nature of the humic substances associated with thevarious soil-clay fractions. The NMR analysis was conductedusing the untreated clay–humic complexes in an effortto avoid bias caused by both selective extraction and chemicalalteration which may occur when humic substances are extractedfrom soil and clay samples. The disadvantage of the approach,however, is that the clay–humic complexes have relativelylow levels of ¹³C and relatively high levels of paramagneticelements (principally Fe³⁺). Paramagnetic elements inhibit crosspolarization thereby masking the NMR signal for ¹³C nuclei thatare proximal to paramagnetic elements. Because of the low signal-to-noiseratio, the spectra are only amenable to qualitative comparisons.The spectra for the coarse clay fraction (Fig. 2a) exhibitsbroad but clearly identifiable peaks in the alkyl (0–50ppm), O-alkyl (50–100 ppm), alkene-aromatic (110–150ppm), and carboxyl (160–190 ppm) regions. By contrast,the spectra for the fine clay (Fig. 2b) has a diffuse peak inthe alkene-aromatic region and two prominent peaks in the alkylregion. The spectra for the whole and medium clay fractions(data not shown) exhibited characteristics intermediate betweenthose of the coarse and fine clay fractions.

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Fig. 2. Solid state-magic angle spinning ¹³C-NMR spectra of the (a) untreated coarse and (b) fine clay fractions from the Webster soil.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS NOTES RESULTS DISCUSSION REFERENCES

The initial noninvasive fractionation procedure used in thisstudy separated clay–humic complexes (the whole soil-clayfraction) from biological materials. The efficacy of the separationin removing biological materials was verified by scanning electronmicroscopy (Laird, 2000). The second invasive fractionationprocedure separated the whole soil clay into coarse, medium,and fine clay fractions which are dominated by quartz, protoillite,and smectite, respectively. These mineralogically distinct fractionscontained similar amounts of OC (Table 2), which indicates thatthe associated humic substances are either chemically bondedto the mineral surfaces or present in discrete particles withsimilar size and density to that of the mineral particles. Ifthe humic substances had been present as discrete low-densityparticles, the OC would have been discarded with the aqueoussupernatant during sample preparation or concentrated in thefine clay fraction.

Chemical, biochemical, and spectroscopic analysis of the varioussoil-clay fractions revealed unique characteristics for theOM associated with each of the mineralogically significant fractions.The OM associated with the coarse clay fraction has a higherC/N ratio, lower levels of extractable amino acids, fatty acids,monosaccharides, amino sugars, and stronger carboxyl and O-alkyl¹³C-NMR peaks relative to the OM associated with the fine andmedium clay fractions. If humic substances had been randomlyassociated with the different clay minerals, the chemical natureof the humic substances associated with the coarse, medium,and fine clay fractions would have been similar. Thus, the observeddifferences demonstrate specificity for the relationship betweensoil-clay mineralogy and humic substances.

The biochemical analyses of the clay–humic complexes determinedthat arginine and lysine are the most abundant amino acids followedby aspartic acid and glutamic acid. Glucosamine which derivedfrom chitin found in fungal hyphae is the most abundant aminosugar in the clay–humic complexes. Arabinose is the mostabundant monosaccharide measured followed by galactose and xylose.Oades (1984) suggested that a ratio <0.5 of galactose plusmannose/arabinose plus xylose is typical of plant derived monosaccharidesand a ratio of >2 is characteristic of microbial carbohydrates.The ratio decreases from 1.03, 0.81, to 0.62 for the coarse,medium, and fine clay, respectively, suggesting more of a plantsource for the monosaccharides in the clay–humic complexesthan a microbial source. The low levels of glucose in the extractssuggest that this monosaccharide is predominately decomposedby soil organisms and not sequestered on clay surfaces. Fattyacids are a major component of the C from the clay fractions(Table 3) and 67 to 76% of the FAMEs isolated from the clayfractions were unsaturated C18 (octadecene fatty acids) as confirmedby mass spectrum analysis. Low levels of C14:0, C15:0, and C16:0FAME's were also identified. Arao (1999) reported that the unsaturatedC18 FAME's are predominately found in fungi while the saturatedFAME's are biomarkers for bacteria. P-hydroxycinnamic acid wasthe predominate phenolic acid extracted with lower levels ofsyringic acid and syringaldehyde confirmed by mass spectrumanalysis. Hydroxycinnamic acids are important components ofplant cell walls (Provan et al., 1994) suggesting that the clayassociated compounds reflect both a microbial and a plant source.

Although the biochemical analysis accounted for <52% of thetotal C in the clay–humic complexes, the results are generallyconsistent with the ¹³C NMR analysis. The relatively strongalkyl peaks in the ¹³C NMR spectra are consistent with the highlevels of extractable fatty acids and amino acids found in thesamples. The small and even absent O-alkyl ¹³C NMR peaks areconsistent with the very low levels of extractable monosaccharidesand amino sugars in the clay–humic complexes. Even theabsence of extractable phenolic acids is not necessarily inconsistentwith the ¹³C NMR spectra. Alkene and aromatic C are not resolvedin the ¹³C NMR spectra, hence the relatively strong peaks inthe 110 to 150 ppm region (Fig. 2) could be because of alkeneC in the unsaturated fatty acids rather than aromatic C. Onthe other hand, the results of the ¹³C NMR and biochemical analysescontrast with published analyses for whole soils. Analysis ofbiochemicals extracted from whole soils generally indicate 5to 25% carbohydrates, 2 to 6% fats, waxes, and resins, and 2to 30% phenolic acids (Stevenson, 1994). And ¹³C NMR analysesof whole soils and humic acids extracted from whole soils typicallyindicate much higher levels of O-alkyl and aromatic C (Stevenson, 1994;Hayes, 1991). The discrepancy between published resultsfor whole soils and the results of this study is attributedto the fact that whole soils contain both clay–humic complexesand biological materials, whereas the samples used in this studycontain only clay–humic complexes. Thus the results suggestthat both monosaccharides and phenolic acids are dominantlyassociated with biological materials rather than clay–humiccomplexes.

The large enrichment of arginine in the clay–humic complexesrelative to levels of arginine in whole soils (4 to 5.5% oftotal amino acids; Senwo and Tabatabai, 1998) suggest that arginineactively accumulates in the clay–humic complexes. Arginineis the most basic of the 20 ${alpha}$ -amino acids in biological systems.Thus the positively charge guanidinium group (pKa = 12.48) onarginine may bond directly to negative charge sites on basalsurfaces of 2:1 phyllosilicates. This interpretation is consistentwith the relatively small difference in CEC (Table 2) betweenthe untreated and H₂O₂-treated fine clay fraction [0.11 mol(+)kg^-1], which is dominated by smectite, and the much larger differencein CEC between the untreated and H₂O₂-treated coarse clay [0.33mol(+) kg^-1], which is dominated by quartz and other mineralsthat lack permanent charge sites. The interpretation is alsoconsistent with the trend of increasing N content and decreasingC/N ratios with decreasing particle size (i.e., increasing smectitecontent) observed in this and several other studies (Anderson et al., 1981;Tiessen and Stewart, 1983; Catroux and Schnitzer, 1987).

Previously, both adsorption and desorption of atrazine werequantified for the same soil clay fractions (Laird et al., 1994).The study revealed a substantial decrease in the affinity ofthe coarse clay fraction for atrazine following the H₂O₂-treatmentand only a minor decrease in the affinity of the fine clay fractionfor atrazine following the H₂O₂-treatment. The results indicatethat humic substances associated with the coarse clay have amuch higher affinity for atrazine than the humic substancesassociated with the fine clay. Wu et al. (1999), using similarprocedures, found that the humic substances associated withthe coarse clay fraction of a Zook soil (fine, smectitic, mesicCumulic Vertic Endoaquolls) have a much higher affinity forCu than the humic substances associated with medium or fineclay fractions. The mineralogy of the clay fractions separatedfrom the Zook soil is similar to the mineralogy of the clayfractions separated from the Webster soil. Thus, considerableevidence indicates that the humic substances which are physicallyseparated with the different soil clay minerals are functionallydifferent as well as chemically, biochemically, and spectroscopicallydifferent.

The observed relationship between clay mineralogy and the chemicalnature of the associated humic substances indicates that eithersoil clay mineralogy strongly influences the humification processor that humic substances with different properties are selectivelyadsorbed on different clay mineral species. Based on the presentstudy it is not possible to distinguish which of the two processes(or both) are responsible for the observed differences in theclay associated humic substances. Regardless of which processis involved, it is apparent that a full understanding of humificationand C-sequestration mechanisms cannot be obtained by a prioriextraction of humic and fulvic acids from soils, but must includean understanding of the influence of clay mineralogy on humification.In the second paper of this series (Laird, 2001), scanning electronmicroscopy is used to further elucidate the relationships betweenhumic substances and soil clay mineralogy.

NOTES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

^¹ Names are necessary to report factually on available data; however,the USDA neither guarantees nor warrants the standard of theproduct, and the use of the name by USDA implies no approvalof the product to the exclusion of others that might also besuitable.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
NOTES
RESULTS
DISCUSSION
REFERENCES

Anderson, D.W., S. Sarrar, J.R. Bettany, and J.W.B. Stewart. 1981. Particle size fractions and their use in studies of soil organic matter: I. The nature and distribution of forms of carbon, nitrogen, and sulfur. Soil Sci. Soc. Am. J. 45:767–772.[Abstract/Free Full Text]

Arao, T. 1999. In situ detection of changes in soil bacterial and fungal activities by measuring 13C incorporation into soil phospholipid fatty acids from 13C acetate. Soil Biol. Biochem. 31:1015–1020.

Arshad, M.A., and L.E. Lowe. 1966. Fractionation and characterization of naturally occurring organo-clay complexes. Soil Sci. Soc. Am. Proc. 30:731–735.

Bailey, S.W., G.W. Brindley, H. Kodama, and R.T. Martin. 1982. Report of the Clay Minerals Society Nomenclature Committee for 1980 and 1981: Nomenclature for regular interstratifications. Clays Clay Miner. 30:76–78.[Abstract]

Bosetto, M., P. Arfaioli, O.L. Pantani, and G.G. Ristori. 1997. Study of the humic-like compounds formed from L-tyrosine on homoionic clays. Clay Minerals 32:341–349.

Bruce, J.P., M. Frome, E. Haites, H. Janzen, R. Lal, and K. Paustian. 1999. Carbon sequestration in soils. J. Soil Water Conserv. 54:382–386.

Catroux, G., and M. Schnitzer. 1987. Chemical, spectroscopic, and biological characteristics of the organic matter in particle size fractions separated from an Aquoll. Soil Sci. Soc. Am. J. 51:1200–1207.[Abstract/Free Full Text]

Frostegard, A., E. Baath, and A. Tunlid. 1993. Shifts in the structure of soil microbial communities in limed forests as revealed by phospholipid fatty acid analysis. Soil Biol. Biochem. 25:723–730.

Hayes, M.H.B. 1991. Concepts of the origins, composition, and structure of humic substances. In W.S. Wilson (ed.) Advances in soil organic matter research: The impact on agriculture and the environment. The Royal Society of Chemistry, Cambridge, UK.

Jackson, M.L. 1985. Soil chemical analysis—Advanced course. 2nd ed. p. 100–166. Madison, WI.

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				M. K. Shukla, R. Lal, and D. VanLeeuwen Spatial Variability of Aggregate-Associated Carbon and Nitrogen Contents in the Reclaimed Minesoils of Eastern Ohio Soil Sci. Soc. Am. J., September 28, 2007; 71(6): 1748 - 1757. [Abstract] [Full Text] [PDF]

				D. A. Martens, D. B. Jaynes, T. S. Colvin, T. C. Kaspar, and D. L. Karlen Soil Organic Nitrogen Enrichment Following Soybean in an Iowa Corn-Soybean Rotation Soil Sci. Soc. Am. J., February 2, 2006; 70(2): 382 - 392. [Abstract] [Full Text] [PDF]

				C. Crecchio, P. Ruggiero, M. Curci, C. Colombo, G. Palumbo, and G. Stotzky Binding of DNA from Bacillus subtilis on Montmorillonite-Humic Acids-Aluminum or Iron Hydroxypolymers: Effects on Transformation and Protection against DNase Soil Sci. Soc. Am. J., May 6, 2005; 69(3): 834 - 841. [Abstract] [Full Text] [PDF]

				J. M. Gonzalez, J. M. Gonzalez, and D. A. Laird ROLE OF SMECTITES AND Al-SUBSTITUTED GOETHITES IN THE CATALYTIC CONDENSATION OF ARGININE AND GLUCOSE Clays and Clay Minerals, August 1, 2004; 52(4): 443 - 450. [Abstract] [Full Text] [PDF]

				J. M. Gonzalez and D. A. Laird Carbon Sequestration in Clay Mineral Fractions from 14C-Labeled Plant Residues Soil Sci. Soc. Am. J., November 1, 2003; 67(6): 1715 - 1720. [Abstract] [Full Text] [PDF]

				M. Kahle, M. Kleber, M. S. Torn, and R. Jahn Carbon Storage in Coarse and Fine Clay Fractions of Illitic Soils Soil Sci. Soc. Am. J., November 1, 2003; 67(6): 1732 - 1739. [Abstract] [Full Text] [PDF]

				D. Laird Nature of Clay-Humic Complexes in an Agricultural Soil: II. Scanning Electron Microscopy Analysis Soil Sci. Soc. Am. J., September 1, 2001; 65(5): 1419 - 1425. [Abstract] [Full Text] [PDF]