Abstract
The large difference in the degree of discrimination of stable carbon isotopes between C3 and C4 plants is widely exploited in global change and carbon cycle research, often with the assumption that carbon retains the carbon isotopic signature of its photosynthetic pathway during later stages of decomposition in soil and sediments. We applied long-term incubation experiments and natural C-13-labelling of C3 and C4-derived soil organic carbon (SOC) collected from across major environmental gradients in Australia to elucidate a significant difference in the rate of decomposition of C3- and C4-derived SOC. We find that the active pool of SOC (ASOC) derived from C4 plants decomposes at over twice the rate of the total pool of ASOC. As a result, the proportion of C4 photosynthesis represented in the heterotrophic CO2 flux from soil must be over twice the proportional representation of C4-derived biomass in SOC. This observation has significant implications for much carbon cycle research that exploits the carbon isotopic difference in these two photosynthetic pathways.
Original language | English |
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Pages (from-to) | 2206-2217 |
Number of pages | 12 |
Journal | Global Change Biology |
Volume | 13 |
Issue number | 10 |
DOIs | |
Publication status | Published - Oct 2007 |
Keywords
- C3-plants
- C4
- decomposition rate
- soil organic carbon
- stable carbon isotope
- ISOTOPE COMPOSITION
- C-13 DISCRIMINATION
- ELEMENTAL CARBON
- LIGNIN CONTROL
- DYNAMICS
- CO2
- ABUNDANCE
- FRACTIONATION
- RESPIRATION
- INDICATORS