Origin of positive delta(13)C of emitted CO(2) from soils after application of biogas residues

RR Senbayram M Lin XG et al.. Origin of positive delta(13)C of emitted CO(2) from soils after application of biogas residues. Soil Biology & Biochemistry 2011 43(10): 2194-2199. (IF 3.242 农林科学，一区）

Abstract

    Bioenergy production from renewable organic material is known to be a clean energy source and therefore its use is currently much promoted in many countries. Biogas by-products also called biogas residues (BGR) are rich in partially stable organic carbon and can be used as an organic fertilizer for crop production. However so far many environmental issues relevant when BGR are applied to agricultural land (soil C sequestration increased denitrification and nutrient leaching) still have to be studied. Therefore a field experiment was set up to investigate the degradation of BGR and its impact on the decomposition of native soil organic matter based on a natural abundance stable isotope approach. Maize a C₄ plant has been used as bioenergy crop therefore the δ¹³C of total C in BGR was −16.0‰_PDB and soil organic matter was mostly derived from C₃ plant based detritus SOM thus showed a δ¹³C of −28.4‰_PDB. Immediately after BGR application soil-emitted CO₂ showed unexpectedly high δ¹³C of up to +23.6‰_PDB which has never been reported earlier. A subsequent laboratory scale experiment confirmed the positive δ¹³C of soil-emitted CO₂ after BGR addition and showed that obviously the added BGR led to a consumption of dissolved inorganic C in soils. Additionally it was observed that the δ¹³C of CO₂ driven from inorganic C of BGR (BGR-IC) by acid treatment was +35.6‰_PDB. Therefore we suggest that also under field conditions the transformation of BGR-IC into CO₂ contributed largely to CO₂ emissions in addition to the decomposition of organic matter which affected both the amount and the carbon isotope signature of emitted CO₂ in the initial period after BGR application. Positive δ¹³C of inorganic C contained in BGR was attributed to processes with strong fractionation of C isotopes during anaerobic fermentation in the biogas formation process.