期刊
RADIOCARBON
卷 61, 期 2, 页码 573-586出版社
UNIV ARIZONA DEPT GEOSCIENCES
DOI: 10.1017/RDC.2018.128
关键词
C-13; C-14; biochar; degradation; immobilization; respiration
资金
- Australian Research Council Laureate Fellowship [FL140100044]
- ANSTO Portal Grant [PE10105]
- Australian Government for the Centre for Accelerator Science at ANSTO
Pyrolized carbon in biochar can sequester atmospheric CO2 into soil to reduce impacts of anthropogenic CO2 emissions. When estimating the stability of biochar, degradation of biochar carbon, mobility of degradation products, and ingress of carbon from other sources must all be considered. In a previous study we tracked degradation in biochars produced from radiocarbon-free wood and subjected to different physico-chemical treatments over three years in a rainforest soil. Following completion of the field trial, we report here a series of in-vitro incubations of the degraded biochars to determine CO2 efflux rates, C-14 concentration and delta C-13 values in CO2 to quantify the contributions of biochar carbon and other sources of carbon to the CO2 efflux. The C-14 concentration in CO2 showed that microbial degradation led to respiration of CO2 sourced from indigenous biochar carbon (approximate to 0.5-1.4 mu moles CO2/g biochar C/day) along with a component of carbon closely associated with the biochars but derived from the local environment. Correlations between C-14 concentration, delta C-13 values and Ca abundance indicated that Ca2+ availability was an important determinant of the loss of biochar carbon.
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