Organic matter in particle-size fractions from A and B horizons of a Haplic Alisol

M. W.I. Schmidt, I. Kögel-Knabner

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53 Scopus citations

Abstract

The organic matter in soils may be stabilized by its interactions with minerals. We have studied such interactions in a Haplic Alisol under forest in which clay and organic matter have migrated from an eluvial A horizon to accumulate in an illuvial B horizon. We have tried to trace the fate of organic matter in these horizons (Ah and Bvt) by determining clay mineralogy, carbon and nitrogen content, hydrolysable amino acids, lignin signature by alkaline CuO oxidation and carbon species by 13C CPMAS NMR of bulk soils and particle-size fractions. In both horizons, most of the organic matter was present in O-alkyl and methylene structures, each contributing one-third to the bulk organic matter. In the Ah horizon the ratios of carbon-to-nitrogen, and yields for lignin and hydrolysable amino acids decreased as the particle-size class decreased, but side-chain oxidation of lignin compounds increased with decreasing particle size. In contrast to previous observations, the proportions of O-alkyl carbon increased as particle size decreased, constituting a major proportion of the organic carbon in the clay-size fractions from both the Ah and Bvt horizons (≥ 38%), while proportions of methylene carbon decreased. Illite was the dominant mineral in the fraction ≤ 6 μm, whereas the mobile fine clay fraction (<0.2 μm) was rich in smectites - minerals with large surface areas. Our results support the hypothesis that potentially labile organic matter, such as O-alkyl carbon typically present in polysaccharides, may be stabilized against further degradation in organomineral complexes.

Original languageEnglish
Pages (from-to)383-391
Number of pages9
JournalEuropean Journal of Soil Science
Volume53
Issue number3
DOIs
StatePublished - Sep 2002

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