Organic-carbon fractions in an agricultural topsoil assessed by the determination of the soil mineral surface area

According to recent conceptual models, the organic carbon (OC) of soils can be divided into OC fractions of increasing stability from labile free OC to resistant OC associated with the soil mineral phase. In this study, we present a method for quantifying two OC fractions based on soil aggregate-siz...

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Bibliographic Details
Published in:Journal of plant nutrition and soil science 2010-10, Vol.173 (5), p.699-705
Main Authors: Séquaris, Jean-Marie, Guisado, Gregorio, Magarinos, Maria, Moreno, Carlos, Burauel, Peter, Narres, Hans-Dieter, Vereecken, Harry
Format: Article
Language:English
Subjects:
clay-associated OC
mineral specific surface area
N2 gas-adsorption method
OC fractions
OC sequestration
soil physical fractionation
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Summary:According to recent conceptual models, the organic carbon (OC) of soils can be divided into OC fractions of increasing stability from labile free OC to resistant OC associated with the soil mineral phase. In this study, we present a method for quantifying two OC fractions based on soil aggregate-size fractionation and the N₂ gas-adsorption method. For this purpose, we analyzed soil material of the plow layer of a Haplic Chernozem subjected to different fertilizer treatments (no fertilizer, mineral fertilizer, mineral and organic fertilizer). The total organic-C concentration (TOC) and the clay content of the different size fractions were determined as well as the specific surface area (SSAmineral) and the sample pore volume after thermal oxidation (OC-free). The TOC of the different soil-aggregate fractions was linearly related to SSAmineral. Clay-associated OC and nonassociated OC fractions of the different soil samples were quantified using two methods based on the OC surface loading at the clay fraction. The application of organic fertilizer increased the amount of nonassociated OC but hardly affected the concentration of clay-associated OC. This finding agrees with previous studies on C dynamics in soils and indicates a finite capacity of soil materials to sequester OC. Even without any addition of organic fertilizer, the mineral phase of the analyzed soil material appears to be C-saturated.
ISSN:1436-8730
1522-2624
DOI:10.1002/jpln.200800224