Effect of land use change on soil carbon in Hawaii

Organic carbon storage and turnover were altered in soils formed from volcanic ash (Andisols) as a result of conversion of tropical forest to pasture and sugarcane cropland. Changes in soil carbon storage after approximately a century of each land use were estimated using stable carbon isotope value...

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Veröffentlicht in:	Biogeochemistry 2003-09, Vol.65 (2), p.213-232
Hauptverfasser:	Osher, L.J, Matson, P.A, Amundson, R
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Sprache:	eng
Schlagworte:	Agricultural land Agricultural soils Agrology Andisols Animal and plant ecology Animal, plant and microbial ecology biogeochemical cycles Biological and medical sciences Carbon Carbon isotopes Carbon sequestration Decomposing organic matter Earth sciences Earth, ocean, space Exact sciences and technology Forest soils Fundamental and applied biological sciences. Psychology Humus Isotope geochemistry Isotope geochemistry. Geochronology Land use Organic carbon Organic soils Pasture Pastures Soil depth Soil horizons Soil organic carbon soil organic matter Soils Sugarcane Surficial geology Synecology Terrestrial ecosystems Tropical forests Tropical soils Turnover time
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creator	Osher, L.J Matson, P.A Amundson, R
description	Organic carbon storage and turnover were altered in soils formed from volcanic ash (Andisols) as a result of conversion of tropical forest to pasture and sugarcane cropland. Changes in soil carbon storage after approximately a century of each land use were estimated using stable carbon isotope values and carbon contents. Total organic carbon stored in soils varied as a result of management, with pasture soils showing net carbon gain and sugarcane soils showing net carbon loss. In pasture soils, increases in carbon at depth (40 to 80 cm) are below the rooting zone of the introduced (C4) vegetation, and have stable carbon isotopic values indicative of forest (C3) plants. Within the pasture rooting zone (0-40 cm) the isotopic data reveals that additions of pasture (C4) organic matter have been offset by losses of C3 carbon. The concentration of Fe/Al oxides (soil minerals that bind with organic matter to form oxide-humus complexes) appear to control the quantity of carbon stored in soils, as well as the difference in the depth and magnitude of carbon storage changes that occur with each type of land use change. Sugarcane land use appears to induce dissociation of Fe/Al oxide-humus complexes and loss of oxide-associated organic matter from the profile. In pastures, Fe/Al oxide-humus complexes are translocated to deeper horizons in the soils, resulting in greater profile carbon storage and longer apparent turnover time of carbon stored below 50 cm depth. In this high precipitation region, carbon losses from the soil appear to occur via downward transport, either as colloids or in solution, in addition to the generally assumed pathway of flux to the atmosphere as CO2.
doi_str_mv	10.1023/A:1026048612540
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Sugarcane land use appears to induce dissociation of Fe/Al oxide-humus complexes and loss of oxide-associated organic matter from the profile. In pastures, Fe/Al oxide-humus complexes are translocated to deeper horizons in the soils, resulting in greater profile carbon storage and longer apparent turnover time of carbon stored below 50 cm depth. 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subjects	Agricultural land Agricultural soils Agrology Andisols Animal and plant ecology Animal, plant and microbial ecology biogeochemical cycles Biological and medical sciences Carbon Carbon isotopes Carbon sequestration Decomposing organic matter Earth sciences Earth, ocean, space Exact sciences and technology Forest soils Fundamental and applied biological sciences. Psychology Humus Isotope geochemistry Isotope geochemistry. Geochronology Land use Organic carbon Organic soils Pasture Pastures Soil depth Soil horizons Soil organic carbon soil organic matter Soils Sugarcane Surficial geology Synecology Terrestrial ecosystems Tropical forests Tropical soils Turnover time
title	Effect of land use change on soil carbon in Hawaii
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