Persistent Organic Pollutants in Native Grassland Soils along a Climosequence in North America

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DIVISION S-7-FOREST & RANGE SOILS

Persistent Organic Pollutants in Native Grassland Soils along a Climosequence in North America

Wolfgang Wilcke and Wulf Amelung

Institute of Soil Science and Soil Geography, University of Bayreuth, D-95440 Bayreuth, Germany

wolfgang.wilcke{at}uni-bayreuth.de

ABSTRACT

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ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

Among the controls on the fate of harzardous persistent organicpollutants (POPs) in the environment, soil organic matter (SOM)and climate play an outstanding role. Thus, it may be possibleto predict POP concentrations at background sites from SOM propertiesand climatic elements. We therefore related polycyclic aromatichydrocarbon (PAH) and polychlorinated biphenyl (PCB) concentrationsin 18 mollic epipedons under native grassland to SOM properties(lignin-derived phenols, polycarboxylic benzoic acids [PCBAs],aromaticity, and polarity of alkali-extractable SOM) and climaticelements. The sum of 20 PAH ( ${sum}$ 20PAHs) concentrations ranged from63 to 321 µg kg^-1, and that of 14 PCB ( ${sum}$ 14PCBs) concentrationsranged from 7.9 to 93 µg kg^-1, except at one contaminatedsite (3136 µg kg^-1). On average, phenanthrene (PHEN, 38%of the ${sum}$ 20PAHs concentrations) and naphthalene (NAPH, 28%) werethe most abundant PAHs, congeners 28 (22% of the ${sum}$ 14PCB concentrations)and 101 (17%) were the most abundant PCBs. Soil organic C (SOC)concentrations correlated with the ${sum}$ 20PAHs concentrations; theC concentration in the sum of eight PCBAs, a marker for blackC, correlated with the concentrations of higher molecular weightPAHs, except in soils with cyric temperature regime. The ${sum}$ 14PCBsconcentrations was independent of any soil property. The contributionof NAPH to the ${sum}$ 20PAHs concentrations and that of the up to tetra-chlorinatedPCBs to the ${sum}$ 14PCBs concentrations decreased with increasingmean annual temperature (MAT). The percentages of PCB 101 increasedwith increasing MAT. However, the temperature effect was notstrong. Mean annual precipitation (MAP) neither effected PAHnor PCB patterns. Our results indicate that the easily measuredSOC concentrations may be used to predict PAH concentrationsin native grassland soils of the prairie. Including MAT improvesthe prediction of NAPH concentrations. The influence of MATon PCB concentrations is obvious, but the correlation is tooweak to be used for reliable predictions.

Abbreviations: ACEN, acenaphthene • ACENY, acenaphthylene • ANTH, anthracene • B(A)A, benz(a)anthracene • B(A)P, benzo(a) pyrene • B(BJK), benzo(b+j+k)fluoranthenes • B(E)P, benzo(e)pyrene • B(GHI), benzo(ghi)perylene • CHRY, chrysene+triphenylene • DIBE, dibenz(a,h)anthracene • DOM, dissolved organic matter • FLUA, fluoranthene • FLUO, fluorene • IND, indeno(1,2,3-cd)pyrene • K_OC, soil solution–soil solid phase partitioning coefficient normalized to the fraction of organic C • K_OW, octanol–water partitioning coefficient • MAP, mean annual precipitation • MAT, mean annual temperature • NAPH, naphthalene • NMR, nuclear magnetic resonance • PAH, polycyclic aromatic hydrocarbon • PCBA, polycarboxylic benzoic acid • PCB, polychlorinated biphenyl • PERY, perylene • PHEN, phenanthrene • POP, persistent organic pollutant • PYR, pyrene • SOC, soil organic C • SOM, soil organic matter • VSC-lignin, sum of the concentrations of vanyllil, syringyl, and cinnamyl phenolic CuO oxidation products • ${sum}$ 20PAHs, sum of 20 PAHs • ${sum}$ 14PCBs, sum of 14 PCBs

Abbreviations: *Significant at the 0.05 level of probability

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

THE GREAT PLAINS are a unique grassland environment extendingacross a wide range of temperature and moisture regimes. Theirsoils, mainly Mollisols, are among the most fertile in the world(Aandahl, 1982). Since most of the Great Plains region is remotefrom major industrial areas, contamination of soils with organicpollutants should be low. Large parts of the Great Plains maytherefore be considered as a typical background area with respectto soil pollution via atmospheric deposition.

The most important sorbent of POPs such as the PAHs and PCBsin soils is organic matter (Strek and Weber, 1982; Sims andOvercash, 1983). Furthermore, Gustafsson et al. (1997) foundthat the black C concentration plays an important role in PAHsorption. Black C results from charring of organic material,for example, during vegetation fires, and is ubiquitous in soil(Goldberg, 1985). The sorption of PAHs and PCBs to soil is furthermoreinfluenced by the concentration and quality of dissolved organicmatter (DOM) in soil solution. Increasing DOM concentrationsreduce the extent of POP sorption to soil solid phase. The associationof PAHs with DOM is favored by increasing aromaticity of theDOM (Chiou et al., 1983; Gauthier et al., 1987; McCarthy etal., 1989). Recent work has shown that solid-state SOM qualityalso influences PAH and PCB sorption. Chiou et al. (1998) founda more pronounced sorption of PAHs to sediments than to soilsand assumed that the polarity of organic matter influences PAHsorption. Kile et al. (1999) observed that the C-normalizedpartitioning coefficient between soil or sediment and water(K_OC) of carbon tetrachloride correlated negatively with thepolarity of soil and sediment samples. In their work, polaritywas defined as the sum of the contribution of O-alkyl and carboxylC signals to the total signal in solid-state ¹³C nuclear magneticresonance (NMR) spectra. Schoone et al. (1997) found that thepartition coefficient of pyrene between soil and water correlatednegatively with the polarity of soil (defined as the ratio ofthe sum of O-alkyl and carboxyl C signals to the sum of aryland alkyl C signals in solid-state ¹³C NMR spectra), while norelationship between the partition coefficient of phenanthreneand polarity was observed.

Early work indicated that the octanol–water partitioncoefficient (K_OW) may be used to predict organic contaminantsorption in soils irrespectively of the compound composition(Chiou et al., 1979). Recently, substantial differences in thesorption of PAHs and PCBs to soil have been reported (McGroddyet al., 1996; Gustafsson et al., 1997; Chiou et al., 1998).Polycyclic aromatic hydrocarbons exhibit higher partitioningcoefficients to soil and sediment than PCBs with similar K_OWvalues, which is attributed to a preferred interaction of PAHswith aromatic structures in soil organic matter (Chiou et al., 1998)or in black C (Gustafsson et al., 1997). Thus, SOM qualityand quantity may be more important for PAH than for PCB sorptionto soils.

Theoretical considerations on the global distribution of POPssuggest that climate influences the composition of the PAH andPCB mixture (pattern) in soil (Wania and Mackay, 1996). Warmtemperatures favor volatilization of POPs; cold temperaturesfavor deposition. As a result, there should be a global fractionationof PAHs and PCBs with increasing contributions of the more volatilecompounds to total concentrations from warm to cold climates.However, the model of Wania and Mackay (1986) is restrictedto a single pulse of POPs to the atmosphere in the tropics.The prediction of PAH and PCB patterns is complicated, amongother reasons, by the fact that POPs are not produced by a singlesource but by many sources at various locations of the world,and that they are degraded during atmospheric transport. Transformationprocesses result in similar PAH profiles in the atmosphere allover the temperate zone (Jones et al., 1989; Jacob et al., 1993;Wild and Jones, 1995). Similar technical PCB mixtures have beenused at many localities of the temperate zones from where theyare dispersed and transformed, also resulting in a rather homogenousbackground mixture (Hutzinger et al., 1988). Thus, it may behypothesized that the patterns of PAH and PCB deposited to soilsat background sites (i.e., those far from industrial activities,urban centers, and heavily frequented roads) are similar throughoutthe temperate zone. In soil, PAH and PCB patterns should bemodified by climatic conditions that control volatilizationand degradation processes.

Because the measurement of POP concentrations in soils is labor-and cost-intensive, it would be promising to predict POP concentrationsat background sites from easily measured or already availabledata. This would be possible if strong relationships existedbetween soil properties or climatic conditions and POP concentrations.The objective of our work was therefore (i) to detect possiblerelationships between SOM concentrations and quality and PAHand PCB concentrations and (ii) to assess climatic effects onPAH and PCB patterns in native North American grassland soilsalong a climosequence from Canada to Texas.

Materials and methods

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ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

Study Sites and Soils
Eighteen sites with moderate clay content (170–350 g kg^-1)were selected for sampling in late spring 1994 along temperatureand precipitation transects across the native North Americanprairie (Table 1) . More details about the sampling sites maybe found in Amelung et al. (1998).

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Table 1 Description of the soils under study

We used a core sampler to collect composite samples (0–10cm) from five subsites (200 cm³ core volume at each subsite)in a radial sampling scheme across each site; the distance betweenthe subsites ranged from 10 m (for small site areas) to 100m. All samples were air-dried immediately after sampling inair-conditioned storage rooms (20–25°C, unknown butcomparable air humidity) for 2 d and sieved (<2 mm) priorto chemical analyses. To minimize contamination after air-drying,samples were kept in closed plastic bags that were only openedto remove aliquots for analyses. Minor sorption of PAHs andPCBs to the plastic may have occurred but are considered asnegligibly small. To assess possible sample contamination orvolatilization losses during air-drying, Krauss et al. (2000)compared in our laboratory PAH and PCB concentrations in theextract of one subsample of a field-fresh soil from the surroundingsof the city of Bayreuth, Germany, with those in the extractof another subsample of the same soil air-dried in a storageroom for 8 d. Differences were within the range of analyticalerror for most PAHs and PCBs except for NAPH and PCB 8. Forthese two compounds a loss of ${approx}$ 45% of the initial concentrationsduring drying, probably due to volatilization, occurred. Thus,the concentrations of NAPH and PCB 8 reported here are likelyto be too low. Since air-drying also occurs in the field, weconsider our sample preparation as normalization to a comparablesoil moisture content, although the higher surface area of thebroken sample may have resulted in somewhat higher volatilizationlosses or sample contamination as would occur in the field.There is no reason to expect a systematic change of the NAPHand PCB 8 concentrations along the climosequence due to ourdrying procedure.

Soil Characterization
The pH (0.1 M CaCl₂, soil/solution ratio 1:2.5) and the effectivecation-exchange capacities (1 M NH4-acetate, pH 7) were takenfrom USDA-SCS (1994) for the US soils. In the Canadian soilswe determined pH and cation-exchange capacity with the samemethods as used for the US soils in our laboratory. Total Cof all samples was determined by C/H/N/S-Analyzer (Elementarvario EL, Elementar Analysensysteme GmbH, Darmstadt, Germany).

Soil Organic Matter Properties
Amount and degree of oxidative decomposition of lignin wereestimated using alkaline CuO oxidation at 170°C for 2 h(modified from Hedges and Ertel, 1982). We replaced liquid–liquidextraction by a solid-phase extraction of the phenols usingC-18 (Mallinckrodt Baker, Phillipsburg, NJ) as suggested byKögel (1986). Phenolic oxidation products were dissolvedand derivatized with a 1:1 mixture of pyridine and N,O-bis(trimethylsilyl)trifluoroacetamide(Fluka Chemie, Deisenhofen, Germany), separated by capillarygas chromatography (Ultra 2 fused silica column, 25 m, HewlettPackard, Palo Alto, CA) and detected by a flame ionization detector(data from Amelung et al., 1999). Alkaline CuO oxidation releasesphenols from reactive sites of the lignin macromolecule. Consequently,the sum of vanillyl, syringyl, and cinnamyl phenolic CuO oxidationproducts (VSC-lignin) gives a directly proportional, relativemeasure of the total lignin.

The sum of the polycarboxylic benzoic acids (PCBAs) hemimellitic,trimellitic, trimesic, pyromellitic, mellophanic, prehnitic,benzenepentacarboxylic, and mellitic acids, used as marker forcharred residues (black C), was determined with the method ofGlaser et al. (1998).

For liquid-state NMR measurements, selected samples were extractedthree times with a 1:1 mixture of 0.1 M NaOH and 0.4 M NaF,the ratio of soil to extraction solution was 1:5 (v/v). Theextracts were dialyzed, freeze-dried, redissolved in 0.24 MNaOD, and transferred to a 10-mm NMR tube ( ${approx}$ 2.5 mL) for ¹³C NMRmeasurement. The method followed that of Schnitzer (1982), exceptthat 0.1 M Na₄P₂O₇ was replaced by 0.4 M NaF. For liquid-state¹³C NMR spectra, we used a Bruker Advance DRX 500 spectrometer(Bruker Instruments, Manning Park, MA), spectrometer frequency,125 MHz; inverse-gated decoupling; acquisition time, 0.33 s;delay time, 1.67 s; line-broadening factor, 100 Hz. Chemicalshifts were given in ppm (Hz Mhz^-1) relative to an externalstandard of TSP (3-(trimethylsilyl)propionic-2,2,3,3-d₄ acid,sodium salt) in D₂O. No internal standard was used. The extractionprocedure yielded 21 ± 7% of the total C concentrations.Despite incomplete C extraction, Amelung et al. (1997) foundin five of six cases that SOM composition of U.S. Great Plaintopsoils as assessed by liquid-state NMR spectroscopy was similarto that assessed by solid-state NMR spectroscopy (using cross-polarizationand magic angle spinning).

PAH and PCB Analysis
We determined 20 PAHs and 12 PCBs: naphthalene (NAPH), acenaphthylene(ACENY), acenaphthene (ACEN), fluorene (FLU), phenanthrene (PHEN),anthracene (ANTH), fluoranthene (FLUA), pyrene (PYR), benz(a)anthracene[B(A)A], chrysene+triphenylene (CHRY), benzo(b+j+k) fluoranthenes[B(BJK)], benzo(a)pyrene [B(A)P], benzo(e) pyrene [B(E)P], perylene(PERY), indeno(1,2,3-cd)pyrene (IND), dibenz(a,h)anthracene(DIBE), benzo(ghi)perylene [B(GHI)], PCB congeners 8, 20, 28,52, 101, 118, 138, 153, 180, 199, 206, and 209 (numbers accordingto Ballschmiter and Zell, 1980).

The samples were extracted with hexane–acetone 2:1 (v/v)in an Accelerated Solvent Extractor (Dionex ASE 200, Dionex,Sunnyvale, CA). Between 3 and 25 g of the soil samples weretransferred into 22-mL extraction cells. The cells were filledwith solvent, pressurized to 14 MPa and heated to 120°Cfor 6 min. Pressure and temperature were held for a static extractiontime of 5 min; afterwards the cells were rinsed with cold solvent(60% of cell volume) and purged with Ar for 150 s. This extractioncycle was performed twice for each sample and the extracts werecombined.

All samples were purified with a column filled with 2 g of aluminumoxide (5% deactivated, upper part) and 2 g of silica (5% deactivated,lower part) and sequentially eluted with 15 mL hexane, 5 mLhexane–dichloromethane 9:1, and 20 mL hexane–dichloromethane4:1. The eluates were combined and evaporated to ${approx}$ 0.1 mL beforePAH measurement. For the determination of PCBs, the extractswere additionally purified with an acid–base silica column,that is, a column filled with (from top to bottom) 0.5 g 22%H₂SO₄-modified silica, 2.5 g 44% H₂SO₄-modified silica, 0.5g activated silica, and 2.5 g 33% NaOH-modified silica. ThePCBs were eluted from the column with 60 mL of hexane and evaporatedto ${approx}$ 0.1 mL prior to analysis.

A Hewlett-Packard 5890 Series II gas chromatograph equippedwith a Hewlett-Packard 5-MS fused silica capillary column (30m by 0.25 mm by 0.25 µm) was used with He as carrier gas(constant pressure mode 80 kPA) and splitless injection (HewlettPackard, Palo Alto, CA). Compounds were detected with a HewlettPackard 5971 A mass selective detector with electron impactionization in selected ion monitoring mode (Hewlett Packard).Details on the temperature program are given in Wilcke et al. (1999a)for the PAHs and in Wilcke et al. (1999b) for the PCBs.

Eight deuterated PAHs [NAPH-D₈, ACEN-D₁₀, FLUO-D₁₀, ANTH-D₁₀,PYR-D₁₀, chrysene-D₁₂, PERY-D₁₂, B(GHI)-D₁₂] and seven ¹³C-labeledPCBs (congeners 28, 52, 101, 138, 153, 180, 209) were used asinternal standards and spiked to the soil samples prior to extraction.Fluoranthene-D₁₀ was spiked as a recovery standard to the extractsprior to injection into the gas chromatograph. The principlesof the quantification method are explained in detail in Kjeller (1998).The average recoveries of the internal standards rangedfrom 69 (NAPH-D₈) to 94% (ANTH-D₁₀) for the PAHs (n = 35) andfrom 84 (¹³C-PCB 28) to 91% (¹³C-PCB 138) for the PCBs (n =33).

To eliminate the influence of a possible laboratory backgroundcontamination the PAH and PCB concentrations were correctedby subtracting the average of four analytical blanks. All analyseswere performed duplicate or repeated until the coefficient ofvariation of the sum of PAH and PCB concentrations between tworeplicates was <10%.

Statistical Analysis
Statistical analysis was performed with STATISTICA for Windows5.1 (StatSoft, Loll and Nielsen, Hamburg, Germany). The correlationanalyses followed the least squares method. Significance wasset at P < 0.05.

Results and discussion

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ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

Sum of PAH and PCB Concentrations
The ${sum}$ 20PAHs concentrations at all sites are similar to ruralbackground concentrations in Europe (Table 2 , Jones et al.,1989; Berset and Holzer, 1995). The ${sum}$ 14PCBs concentrations areelevated at most sites when compared with background concentrationsin European soils (Table 3 , Creaser et al., 1989; Harrad etal., 1994; Berset and Holzer, 1995). However, the ${sum}$ 14PCBs concentrationsare less than those in urban soils (Weiss et al., 1994; Wilckeand Zech, 1998) and below the intervention value of the Dutchlist (1000 µg kg^-1) requiring remediation (Rosenkranz et al., 1995)except for the soil at Site XII. The Dutch listis frequently used as reference to assess the degree of soilcontamination. Site XII, although located in a protected area(Konza prairie in Kansas), is heavily contaminated with PCBs.The soil at this site also exhibits the highest ${sum}$ 20PAHs concentration.While elevated PAH concentrations may be related to frequentfires, the elevated PCB concentrations indicate specific depositionof POP-contaminated materials.

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Table 2 Polycyclic aromatic hydrocarbon (PAH) concentrations in North American native grassland topsoils (0–10 cm). ${dagger}$

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Table 3 Polychlorinated biphenyl (PCB) concentrations in North American native grassland topsoils (0–10 cm)

PAH and PCB Patterns
The PAH patterns are clearly dominated by the relatively volatilerepresentatives PHEN (on average 38% of ${sum}$ 20PAHs concentrations)and NAPH (28%, Table 2). All other PAHs, on average, individuallyaccount for <10% of the sum of PAH concentrations, with FLUAbeing the most abundant compound (9.6%). The result confirmsthat the study sites are located far from large industrial andvehicular PAH sources that frequently result in PAH patternsdominated by FLUA, CHRY, and B(BJK) as in urban soils (Bradleyet al., 1994; Weiss et al., 1994; Berset and Holzer, 1995).As low molecular weight PAHs are more volatile, they remainin the atmosphere for longer periods and are thus more susceptibleto long-distance transport compared with the higher molecularweight PAHs. The soil at Site XII is characterized by the highestpercentage of NAPH (55.8%) of the ${sum}$ 20PAHs concentration, whichmay indicate either deposition of NAPH-containing materialsor a recent fire next to or on the site producing mainly NAPH(Freeman and Cattell, 1990).

The most abundant PCBs are congeners 28 (on average 22% of the ${sum}$ 14PCBs concentrations) > 101 (16.8%) > 20 (16.5%). The hexa-chlorinatedcongeners 138 and 153, which dominate quantitatively in manyurban soils (Weiss et al., 1994; Wilcke and Zech, 1998; Wilckeet al., 1999b), only account for 22%. The heavily contaminatedsoil at Site XII exhibits a different PCB pattern with congeners138 and 153 accounting for 36 and 24% of the ${sum}$ 14PCBs concentration,respectively. The results indicate that this site has been specificallycontaminated by deposition of one of the most common technicalPCB mixtures (Hutzinger et al., 1988), while the other sitesprobably received their PCB burden by long-distance atmospherictransport shifting the PCB pattern to the more volatile representatives.Because of the high PCB contamination and the differences inPAH and PCB patterns from the other sites, we qualified thesoil at Site XII as an outlier and omitted it in the furtherdiscussion.

Influence of SOM Concentration
The SOC concentrations correlate significantly with the ${sum}$ 20PAHsconcentrations (Fig. 1) . The fact that the regression linedoes not pass through the origin of the coordinate system indicatesthat there is PAH sorption to soil constituents other than SOM.No correlation has been observed between the concentrationsof SOC and those ${sum}$ 14PCBs or any individual PCB. A range of laboratorywork has shown that the partition coefficient of POPs betweensoil water and soil solid phase increases with increasing organicmatter concentrations (Sims and Overcash, 1983; Marschner, 1999).In the field, a weak correlation between SOC and PAH concentrationshas been observed by Jones et al. (1989) for mainly rural Welshsoils. The correlation between SOC and PAH concentrations maybe interpreted as result of the partitioning of PAHs from theatmosphere to SOM. In our study, the correlation between SOCand PAH concentrations, therefore, supports the hypothesis thatmost of the PAH burden of the grassland soils result from diffusebackground concentrations in the atmosphere.

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Fig. 1 Relationship between soil organic C concentrations and the sum of 14 polychlorinated biphenyl (PCB) ( ${sum}$ 14PCBs, open triangles) and 20 polycyclic aromatic hydrocarbon (PAH) concentrations ( ${sum}$ 20PAHs, closed circles). Site XII was eliminated because it is an outlier

The correlation of the concentrations of SOC with those of ${sum}$ 20PAHsis mainly due to the correlation of the concentrations of themore volatile PAHs NAPH (r = 0.86*), ACENY (0.69*), FLUO (0.69*),PHEN (0.58*), and ANTH (0.73*) with SOC, while there is no correlationbetween the concentrations of SOC and higher molecular weightPAHs. The slopes of the regression lines decrease in the order:NAPH (1.50) > PHEN (0.50) > FLUO (0.09) > ACENY (0.03) > ANTH(0.02). Except for ACENY, the slope reflects the volatilityof the compounds. The more volatile a PAH is, the larger isthe gaseous portion in the atmosphere. The importance of SOMfor PAH sorption should increase with increasing gaseous portionsin the atmosphere, because only gaseous PAHs may be partitioneddirectly from the atmosphere to SOM. The lack of correlationsbetween SOC and higher molecular weight PAHs confirms findingsin the literature that these compounds are deposited in associationwith particles and therefore are not readily available for partitioningto SOM (Meharg et al., 1998).

The lack of correlation between SOC and PCB concentrations mayindicate that PCB background concentrations in the atmosphereare not homogeneous. The sources of PCBs are less homogeneouslydistributed than those of PAHs, because PCBs are mainly usedfor well-defined technical purposes, while PAHs are producedby any combustion process (Sims and Overcash, 1983; Harrad etal., 1994). Thus, the distance of the study site to the nearestPCB source may be more important for PCB concentrations in soilthan it is the case for the PAH concentrations.

Influence of SOM Composition
To obtain a quantitative measure of plant-derived aromatic structureswe determined the concentrations of lignin-derived phenols inthe bulk soil. The sum of eight PCBA concentrations was usedas a marker of charred plant residues. To assess aromaticityand polarity of SOM, we characterized the alkali-extractableportion of SOM with ¹³C NMR spectroscopy. Polarity is definedas the ratio of the percentages of aryl + alkyl C to those ofcarboxyl + carbonyl C of the total ¹³C NMR signal intensity(Schoone et al., 1997).

The VSC-lignin concentrations correlated significantly withthose of the ${sum}$ 20PAHs (r = 0.65*). However, the VSC-lignin andSOC concentrations were also significantly correlated (r = 0.88*)and the correlation between VSC-lignin and ${sum}$ 20PAHs concentrationswas lower than that between SOC and ${sum}$ 20PAHs concentrations. Thiswas also true for the significant correlations between VSC-ligninand NAPH (r = 0.69*), PHEN (0.54*), and ANTH (0.56*) concentrationswhen compared with the respective correlations of SOC and individualPAH concentrations. We therefore conclude that VSC-lignin isnot promoting PAH sorption in the study soils.

When all soils with cryic temperature regimes (Sites I–III)and the soil at Site XII were eliminated from the correlationanalysis, significant correlations between the C concentrationsin the sum of eight PCBAs and the concentrations of all highermolecular weight PAHs (molecular weight > 200 g mol^-1, r = 0.75*–0.89*,n = 11), except for PERY, were observed. The result indicatedthat the accumulation of charred plant residues goes along withthe accumulation of highly condensed PAHs. Thus, higher molecularweight PAHs in the study soils may be derived from vegetationfires. The reason for the particularly high PCBA concentrationsin some soils with cryic temperature regime is unknown becausevegetation fires are common at all study sites (Table 1).

To assess a possible relationship of the PAH and PCB concentrationswith SOM properties determined in the alkali-extracts with ¹³CNMR we normalized the PAH concentrations to those of SOC. Ourintention was to reduce the strong influence of the SOC concentrationson those of the PAHs. We did not find any significant correlationbetween the SOM properties determined with ¹³C NMR and the SOC-normalized ${sum}$ 20PAHs and ${sum}$ 14PCBs concentrations. When the individual PAHs,except NAPH and ACEN, were considered, a negative relationshipbetween aromaticity and SOC-normalized PAH concentrations wasobserved. However, the correlations were not strong (r = -0.36to -0.74) and only significant for FLUO (r = -0.74*) and CHRY(r = -0.64*). Although the properties of alkali-extracted organicmatter determined with liquid-state ¹³C NMR were similar tothose of the total SOM determined with solid-state ¹³C NMR forsome of our study soils (Amelung et al., 1997), this may notbe true for all studied soils. Thus, the conclusion that SOMproperties as determined with ¹³C NMR are not related to POPconcentrations may not be generalized.

Influence of Climate
The percentage of NAPH of the ${sum}$ 20PAHs concentrations and thepercentages of PCBs 20, 28, and 101 of the ${sum}$ 14PCBs concentrationstended to be related with MAT (Fig. 2a–2d) . The correlationfor PCB 101 was significant, but not strong. While the percentagesof NAPH, PCB 20, and PCB 28 decreased with increasing MAT, thoseof PCB 101 increased correspondingly. The strongest relationshipwas observed for the most volatile compound NAPH (vapor pressure:10^1.05 Pa; Mackay et al., 1992b). When soils from Sites XIIand XVII were omitted, the correlation became significant (r= 0.76*, n = 16). As NAPH is one of the major PAHs producedin vegetation fires (Freeman and Cattell, 1990) outliers withhigh NAPH percentages due to a recent vegetation fire near thestudy site should be expected.

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Fig. 2 Relationship between MAT and percentage of the sum of concentrations of (a) naphthalene (NAPH), (b) polychlorinated biphenyl (PCB) 20, (c) PCB 28, and (d) PCB 101. Site XII was eliminated because it is an outlier

Although PCBs with up to three Cl substitutions have vapor pressures(10^-0.55–10^-2.3 Pa; Mackay et al., 1992a) similar to thoseof ACENY, ACEN, FLUO, and PHEN (10^-0.92–10^-1.83; Mackay et al., 1992b),no influence of MAT on the percentages of thesePAHs was observed. This may be the result of a stronger sorptionof PAHs than of PCBs to SOM (Chiou et al., 1998) or to charredplant residues (Gustafsson et al., 1997). We did not observeany significant correlation between mean annual precipitationand PAH or PCB concentrations and patterns.

Naphthalene shows the fastest degradation rate of all PAHs (Simsand Overcash, 1983; Wild and Jones, 1995) and the degradationrates of PCBs decrease with increasing chloro-substitution (Abramowicz, 1990).Thus, the relationship of the percentages of NAPH ofthe ${sum}$ 20PAHs concentrations and the percentages with MAT of PCBs20, 28, and 101 of the ${sum}$ 14PCBs concentrations may also partlybe explained by enhanced degradation of the more easily degradablePAHs and PCBs due to increasing MAT.

Conclusions

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ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
REFERENCES

The PAH concentrations of native grassland soils of the GreatPlains are typical of remote background areas, while the PCBconcentrations are higher than reported for background areasin literature. However, PCB concentrations are not criticalexcept at the Konza prairie in Kansas where we detected a localcontamination.

The correlation between SOC concentrations and con- centrationsof the more volatile low molecular weight PAHs indicated thatthese compounds are partitioned from the atmosphere to SOM.No correlation between SOC and PCB concentrations existed, probablyas a result of the less homogeneous distribution of PCB sourcesand therefore less homogeneous background concentration of PCBsin the atmosphere. The SOM quality as assessed by liquid-state¹³C NMR, VSC-lignin, and PCBA analyses did not correlate with ${sum}$ 20PAHs and ${sum}$ 14PCB concentrations.

Mean annual temperature was correlated with percentages of thetotal concentration of POPs, while mean annual precipitationwas not. The percentages of volatile and easily degradable PAHs(NAPH) and PCBs (congeners 20 and 28) of the total concentrationdecreased with increasing MAT, while the percentages of theless volatile PCB 101 increased. The result that climate hada more pronounced influence on the patterns of PCBs than ofPAHs with similar vapor pressures further supports previousfindings in literature that PAHs are more strongly sorbed toSOM than PCBs.

Our results indicated that the easily measured SOC concentrationsmay be used to predict PAH concentrations in native grasslandsoils of the prairie. Including MAT improves the predictionof NAPH concentrations. The influence of MAT on PCB concentrationsis obvious, but the correlation is too weak to be used for reliablepredictions.Soil Survey Staff 1997; USDA-SCS 1995

ACKNOWLEDGMENTS

We are especially grateful to W. Zech and K.W. Flach for theirimportant support. We thank V.O. Biederbeck, L. Brown, S. Brown,C. Campbell, E. Montemayor, G.R. Carlson, G. Creinwelge, R.F.Follett, D.W. Fryrear, J. Jochim, E. Knox, R. Molina, E.G. Pruessner,C. Richardson, G.E. Schuman, E. Skidmore, D. Sweeney, H. Tiessen,C. Thompson, D. Towns, F. Turner, M. Vorhees, R. Vredenburg,and R. Zink for help with site location and sampling, and AndreaBergmann for contributing to the analyses. We are grateful toB. Glaser for providing the PCBA data and to M. Krauss for valuablediscussions. The work has been supported by the Deutsche Forschungsgemeinschaft(DFG Ze 154/22-3).

Received for publication September 9, 1999.

REFERENCES

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ABSTRACT
INTRODUCTION
Materials and methods
Results and discussion
Conclusions
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