Aufsatz in einer Fachzeitschrift
Is thermal oxidation at different temperatures suitable to isolate soil organic carbon fractions with different turnover?
Details zur Publikation
Autor(inn)en: | Helfrich, M.; Flessa, H.; Dreves, A.; Ludwig, B. |
Publikationsjahr: | 2010 |
Zeitschrift: | Journal of Plant Nutrition and Soil Science |
Seitenbereich: | 61-66 |
Abkürzung der Fachzeitschrift: | J Plant Nutr Soil Sc |
Jahrgang/Band : | 173 |
Heftnummer: | 1 |
Erste Seite: | 61 |
Letzte Seite: | 66 |
ISSN: | 1436-8730 |
DOI-Link der Erstveröffentlichung: |
Zusammenfassung, Abstract
Findings of previous studies suggest that there are relations between thermal stability of soil organic matter (SOM), organo-mineral associations, and stability of SOM against microbial decay. We aimed to test whether thermal oxidation at various temperatures (200 degrees C, 225 degrees C, 275 degrees C, 300 degrees C, 400 degrees C, or 500 degrees C) is capable of isolating SOM fractions with increasing stability against microbial degradation. The investigation was carried out on soils (Phaeozem and Luvisol) under different land-use regimes (field, grassland, forest). The stability of the obtained soil organic carbon (SOC) fractions was determined using the natural-C-13 approach for continuously maize-cropped soils and radiocarbon dating. In the Luvisol, thermal oxidation with increasing temperatures did not yield residual SOC fractions of increasing microbial stability. Even the SOC fraction resistant to thermal oxidation at 300 degrees C contained considerable amounts of young, maize-derived C. In the Phaeozem, the mean C-14 age increased considerably (from 3473 y BP in the mineral-associated SOC fraction to 9116 y BP in the residual SOC fraction after thermal oxidation at 300 degrees C). An increasing proportion of fossil C (calculated based on C-14 data) in residual SOC fractions after thermal oxidation with increasing temperatures indicated that this was mainly due to the relative accumulation of thermally stable fossil C. We conclude that thermal oxidation with increasing temperature was not generally suitable to isolate mineral-associated SOC fractions of increasing microbial stability
Findings of previous studies suggest that there are relations between thermal stability of soil organic matter (SOM), organo-mineral associations, and stability of SOM against microbial decay. We aimed to test whether thermal oxidation at various temperatures (200 degrees C, 225 degrees C, 275 degrees C, 300 degrees C, 400 degrees C, or 500 degrees C) is capable of isolating SOM fractions with increasing stability against microbial degradation. The investigation was carried out on soils (Phaeozem and Luvisol) under different land-use regimes (field, grassland, forest). The stability of the obtained soil organic carbon (SOC) fractions was determined using the natural-C-13 approach for continuously maize-cropped soils and radiocarbon dating. In the Luvisol, thermal oxidation with increasing temperatures did not yield residual SOC fractions of increasing microbial stability. Even the SOC fraction resistant to thermal oxidation at 300 degrees C contained considerable amounts of young, maize-derived C. In the Phaeozem, the mean C-14 age increased considerably (from 3473 y BP in the mineral-associated SOC fraction to 9116 y BP in the residual SOC fraction after thermal oxidation at 300 degrees C). An increasing proportion of fossil C (calculated based on C-14 data) in residual SOC fractions after thermal oxidation with increasing temperatures indicated that this was mainly due to the relative accumulation of thermally stable fossil C. We conclude that thermal oxidation with increasing temperature was not generally suitable to isolate mineral-associated SOC fractions of increasing microbial stability
