The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils

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Original languageEnglish
Pages (from-to)711-725
Number of pages15
JournalOrganic geochemistry
Volume31
Issue number7-8
Publication statusPublished - Jul 2000
Externally publishedYes

Abstract

Sorption of dissolved organic matter (DOM) is considered to be a major process in the preservation of organic matter (OM) in marine sediments. Evidence for this hypothesis includes the close relationship between sediment surface area (SA) and organic carbon (OC) concentrations and the strongly reduced biological degradability after DOM has sorbed to mineral surfaces. The aim of this study was to discuss the possibility of a similar process in the soil environment. We accomplished this by gathering information from the literature, and by an evaluation of our own studies on DOM sorption and accumulation of OM in soil. We found that in soil a close association of OM with the mineral matrix exists. Both the concentration of soil OM associated with the mineral matrix, and the sorption of DOM are related to reactive mineral phases such as A1 and Fe oxyhydroxides. Sorption of DOM derived from the oxidative decomposition of lignocellulose to A1 and Fe oxyhydroxides involves strong complexation bondings between surface metals and acidic organic ligands, particularly with those associated with aromatic structures. The strength of the sorption relates to the surface area but more importantly to the surface properties of the sorbing mineral phase. The sorption of a large part of DOM is hardly reversible under conditions similar to those during sorption (hysteresis). Because sorption of the more labile polysaccharide-derived DOM on mineral surfaces is weaker, adsorptive and desorptive processes strongly favour the accumulation of the more recalcitrant lignin-derived DOM. In addition, we found the soil OM in an alluvial B horizon and in the clay fraction of a topsoil strongly resembling lignin-derived DOM from the overlying forest floors. Hence, it seems likely that sorption of DOM contributes considerably to the accumulation and preservation of OM in soil. However, this does not result in a significant relationship between OC concentration and SA. Reasons for that finding may be the 'masking' of mineral surfaces by adsorbed OM, the clustering of OM patches at highly reactive sites of metal hydroxides, and/or the absence of a relationship between SA and the concentration of surface-active Fe and A1 oxyhydroxides in some soil types. Overall, we conclude that sorptive preservation of OM in soil is affected by the chemical structure of the sorbing DOM and the surface properties of the mineral matrix. Localisation and conformation of sorbed OM remains unclear and therefore should be subject of further research. (C) 2000 Elsevier Science Ltd.

Keywords

    Dissolved organic matter, Mineral surfaces, Preservation of OM, Sorption of DOM

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Sustainable Development Goals

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The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils. / Kaiser, Klaus; Guggenberger, Georg.
In: Organic geochemistry, Vol. 31, No. 7-8, 07.2000, p. 711-725.

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title = "The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils",
abstract = "Sorption of dissolved organic matter (DOM) is considered to be a major process in the preservation of organic matter (OM) in marine sediments. Evidence for this hypothesis includes the close relationship between sediment surface area (SA) and organic carbon (OC) concentrations and the strongly reduced biological degradability after DOM has sorbed to mineral surfaces. The aim of this study was to discuss the possibility of a similar process in the soil environment. We accomplished this by gathering information from the literature, and by an evaluation of our own studies on DOM sorption and accumulation of OM in soil. We found that in soil a close association of OM with the mineral matrix exists. Both the concentration of soil OM associated with the mineral matrix, and the sorption of DOM are related to reactive mineral phases such as A1 and Fe oxyhydroxides. Sorption of DOM derived from the oxidative decomposition of lignocellulose to A1 and Fe oxyhydroxides involves strong complexation bondings between surface metals and acidic organic ligands, particularly with those associated with aromatic structures. The strength of the sorption relates to the surface area but more importantly to the surface properties of the sorbing mineral phase. The sorption of a large part of DOM is hardly reversible under conditions similar to those during sorption (hysteresis). Because sorption of the more labile polysaccharide-derived DOM on mineral surfaces is weaker, adsorptive and desorptive processes strongly favour the accumulation of the more recalcitrant lignin-derived DOM. In addition, we found the soil OM in an alluvial B horizon and in the clay fraction of a topsoil strongly resembling lignin-derived DOM from the overlying forest floors. Hence, it seems likely that sorption of DOM contributes considerably to the accumulation and preservation of OM in soil. However, this does not result in a significant relationship between OC concentration and SA. Reasons for that finding may be the 'masking' of mineral surfaces by adsorbed OM, the clustering of OM patches at highly reactive sites of metal hydroxides, and/or the absence of a relationship between SA and the concentration of surface-active Fe and A1 oxyhydroxides in some soil types. Overall, we conclude that sorptive preservation of OM in soil is affected by the chemical structure of the sorbing DOM and the surface properties of the mineral matrix. Localisation and conformation of sorbed OM remains unclear and therefore should be subject of further research. (C) 2000 Elsevier Science Ltd.",
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author = "Klaus Kaiser and Georg Guggenberger",
note = "Funding information: This research was in parts financed by the Deutsche Forschungsgemeinschaft (joint research program ”ROSIG”). We are grateful to U. Roth and H. Ciglasch for laboratory assistance and in particular to L. Haumaier for recording the NMR spectra and for valuable discussions. We are indebted to W. Zech for his constant support during all phases of this study.",
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Download

TY - JOUR

T1 - The role of DOM sorption to mineral surfaces in the preservation of organic matter in soils

AU - Kaiser, Klaus

AU - Guggenberger, Georg

N1 - Funding information: This research was in parts financed by the Deutsche Forschungsgemeinschaft (joint research program ”ROSIG”). We are grateful to U. Roth and H. Ciglasch for laboratory assistance and in particular to L. Haumaier for recording the NMR spectra and for valuable discussions. We are indebted to W. Zech for his constant support during all phases of this study.

PY - 2000/7

Y1 - 2000/7

N2 - Sorption of dissolved organic matter (DOM) is considered to be a major process in the preservation of organic matter (OM) in marine sediments. Evidence for this hypothesis includes the close relationship between sediment surface area (SA) and organic carbon (OC) concentrations and the strongly reduced biological degradability after DOM has sorbed to mineral surfaces. The aim of this study was to discuss the possibility of a similar process in the soil environment. We accomplished this by gathering information from the literature, and by an evaluation of our own studies on DOM sorption and accumulation of OM in soil. We found that in soil a close association of OM with the mineral matrix exists. Both the concentration of soil OM associated with the mineral matrix, and the sorption of DOM are related to reactive mineral phases such as A1 and Fe oxyhydroxides. Sorption of DOM derived from the oxidative decomposition of lignocellulose to A1 and Fe oxyhydroxides involves strong complexation bondings between surface metals and acidic organic ligands, particularly with those associated with aromatic structures. The strength of the sorption relates to the surface area but more importantly to the surface properties of the sorbing mineral phase. The sorption of a large part of DOM is hardly reversible under conditions similar to those during sorption (hysteresis). Because sorption of the more labile polysaccharide-derived DOM on mineral surfaces is weaker, adsorptive and desorptive processes strongly favour the accumulation of the more recalcitrant lignin-derived DOM. In addition, we found the soil OM in an alluvial B horizon and in the clay fraction of a topsoil strongly resembling lignin-derived DOM from the overlying forest floors. Hence, it seems likely that sorption of DOM contributes considerably to the accumulation and preservation of OM in soil. However, this does not result in a significant relationship between OC concentration and SA. Reasons for that finding may be the 'masking' of mineral surfaces by adsorbed OM, the clustering of OM patches at highly reactive sites of metal hydroxides, and/or the absence of a relationship between SA and the concentration of surface-active Fe and A1 oxyhydroxides in some soil types. Overall, we conclude that sorptive preservation of OM in soil is affected by the chemical structure of the sorbing DOM and the surface properties of the mineral matrix. Localisation and conformation of sorbed OM remains unclear and therefore should be subject of further research. (C) 2000 Elsevier Science Ltd.

AB - Sorption of dissolved organic matter (DOM) is considered to be a major process in the preservation of organic matter (OM) in marine sediments. Evidence for this hypothesis includes the close relationship between sediment surface area (SA) and organic carbon (OC) concentrations and the strongly reduced biological degradability after DOM has sorbed to mineral surfaces. The aim of this study was to discuss the possibility of a similar process in the soil environment. We accomplished this by gathering information from the literature, and by an evaluation of our own studies on DOM sorption and accumulation of OM in soil. We found that in soil a close association of OM with the mineral matrix exists. Both the concentration of soil OM associated with the mineral matrix, and the sorption of DOM are related to reactive mineral phases such as A1 and Fe oxyhydroxides. Sorption of DOM derived from the oxidative decomposition of lignocellulose to A1 and Fe oxyhydroxides involves strong complexation bondings between surface metals and acidic organic ligands, particularly with those associated with aromatic structures. The strength of the sorption relates to the surface area but more importantly to the surface properties of the sorbing mineral phase. The sorption of a large part of DOM is hardly reversible under conditions similar to those during sorption (hysteresis). Because sorption of the more labile polysaccharide-derived DOM on mineral surfaces is weaker, adsorptive and desorptive processes strongly favour the accumulation of the more recalcitrant lignin-derived DOM. In addition, we found the soil OM in an alluvial B horizon and in the clay fraction of a topsoil strongly resembling lignin-derived DOM from the overlying forest floors. Hence, it seems likely that sorption of DOM contributes considerably to the accumulation and preservation of OM in soil. However, this does not result in a significant relationship between OC concentration and SA. Reasons for that finding may be the 'masking' of mineral surfaces by adsorbed OM, the clustering of OM patches at highly reactive sites of metal hydroxides, and/or the absence of a relationship between SA and the concentration of surface-active Fe and A1 oxyhydroxides in some soil types. Overall, we conclude that sorptive preservation of OM in soil is affected by the chemical structure of the sorbing DOM and the surface properties of the mineral matrix. Localisation and conformation of sorbed OM remains unclear and therefore should be subject of further research. (C) 2000 Elsevier Science Ltd.

KW - Dissolved organic matter

KW - Mineral surfaces

KW - Preservation of OM

KW - Sorption of DOM

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U2 - 10.1016/S0146-6380(00)00046-2

DO - 10.1016/S0146-6380(00)00046-2

M3 - Article

AN - SCOPUS:0034233315

VL - 31

SP - 711

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JO - Organic geochemistry

JF - Organic geochemistry

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ER -

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