Journal
GEODERMA
Volume 128, Issue 1-2, Pages 3-17Publisher
ELSEVIER
DOI: 10.1016/j.geoderma.2004.12.022
Keywords
soil organic matter; lignin; C-13 natural abundance; vegetation sequence; C3/C4 plants
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Plant residues incorporated into soils are subjected to contrasted stabilization and biodegradation processes and may contribute to pools of soil organic matter (SOM) displaying difference turnover times. Little is known about the relationship between the chemical structure of plant macromolecules and their long-term turnover in soils. Our research objective was to quantify the in situ turnover of phenols derived from lignin, which is a major component of plant tissues often considered slowly biodegradable relative to total plant organic matter. In this study, we used natural C-13 labeling of SOM generated by a 9-year chronosequence of maize C4 crop (delta(13)C around -12 parts per thousand) replacing g the previous wheat C3 crop (delta(13)C around -27 parts per thousand) at the Closeaux experimental field, in France. Here we present the combined applications of CuO oxidation and gas chromatography coupled via a combustion interface to an isotope ratio mass spectrometer (GC/C-IRA4S) to follow variations in the isotopic composition of lignin-derived monomers in soils of the wheat-maize transition chronosequence. This study aimed at evaluating: (1) the precision and repeatability of this molecular-level isotopic tracer technique, and (2) its potential for computing the proportion of newly derived C in each lignin phenol. Nine years of maize cropping influenced neither the total organic carbon (OC) content nor the lignin content and biodegradation degree in soil. The total SOM after 9 years of maize cropping was significantly enriched in C-13 by 1.4 parts per thousand compared to the wheat soil. In the CuO-derived lignin phenols, the variations of C-13 contents after 9 years of maize cropping ranged from 4.9 parts per thousand to 10.0 parts per thousand, with an average value for total lignin of 7.3 parts per thousand. These variations were well above the precision of the analytical method, calculated for maize plant and soils to be in the range 0.2-0.8 parts per thousand. This study thus demonstrates that the CuO oxidation technique is applicable to the determination of the natural isotopic abundance variations in lignin monomers of soils of a C3/C4 chronosequence. Finally, we could calculate the proportion of newly derived OC after 9 years of maize cropping. This proportion was 9% for total SOM and 47% for lignin, which displayed faster dynamics in this soil than total OC. This study confirms, using in situ labeling technique in combination with lignin monomers analysis after CuO oxidation, that lignin macromolecules are not stabilized as such in these soils. (c) 2004 Elsevier B.V. All rights reserved.
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