Citation Information

  • Title : Linking temperature sensitivity of soil organic matter decomposition to its molecular structure, accessibility, and microbial physiology.
  • Source : Global Change Biology
  • Publisher : Wiley-Blackwell
  • Volume : 19
  • Issue : 4
  • Pages : 1114-1125
  • Year : 2013
  • DOI : 10.1111/gcb.12112
  • ISBN : 1354-1013
  • Document Type : Journal Article
  • Language : English
  • Authors:
    • Shirato, Y.
    • Yonemura, S.
    • Kishimoto-Mo, A. W.
    • Wagai, R.
    • Hiradate, .
    • Yagasaki, Y.
  • Climates: Humid subtropical (Cwa, Cfa).
  • Cropping Systems:
  • Countries: Japan.

Summary

Temperature sensitivity of soil organic matter (SOM) decomposition may have a significant impact on global warming. Enzyme-kinetic hypothesis suggests that decomposition of low-quality substrate (recalcitrant molecular structure) requires higher activation energy and thus has greater temperature sensitivity than that of high-quality, labile substrate. Supporting evidence, however, relies largely on indirect indices of substrate quality. Furthermore, the enzyme-substrate reactions that drive decomposition may be regulated by microbial physiology and/or constrained by protective effects of soil mineral matrix. We thus tested the kinetic hypothesis by directly assessing the carbon molecular structure of low-density fraction (LF) which represents readily accessible, mineral-free SOM pool. Using five mineral soil samples of contrasting SOM concentrations, we conducted 30-days incubations (15, 25, and 35°C) to measure microbial respiration and quantified easily soluble C as well as microbial biomass C pools before and after the incubations. Carbon structure of LFs (<1.6 and 1.6-1.8 g cm -3) and bulk soil was measured by solid-state 13C-NMR. Decomposition Q10 was significantly correlated with the abundance of aromatic plus alkyl-C relative to O-alkyl-C groups in LFs but not in bulk soil fraction or with the indirect C quality indices based on microbial respiration or biomass. The warming did not significantly change the concentration of biomass C or the three types of soluble C despite two- to three-fold increase in respiration. Thus, enhanced microbial maintenance respiration (reduced C-use efficiency) especially in the soils rich in recalcitrant LF might lead to the apparent equilibrium between SOM solubilization and microbial C uptake. Our results showed physical fractionation coupled with direct assessment of molecular structure as an effective approach and supported the enzyme-kinetic interpretation of widely observed C quality-temperature relationship for short-term decomposition. Factors controlling long-term decomposition Q10 are more complex due to protective effect of mineral matrix and thus remain as a central question.

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