Journal Article10.1111/J.1461-0248.2004.00579.X
Carbon input to soil may decrease soil carbon content
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TL;DR: In this article, a negative relationship between primary production and soil carbon (C) content is found, and the authors conclude that energy available to soil microbes and microbial competition are important determinants of soil C decomposition.
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Abstract: It is commonly predicted that the intensity of primary production and soil carbon (C) content are positively linked. Paradoxically, many long-term field observations show that although plant litter is incorporated to soil in large quantities, soil C content does not necessarily increase. These results suggest that a negative relationship between C input and soil C conservation exists. Here, we demonstrate in controlled conditions that the supply of fresh C may accelerate the decomposition of soil C and induce a negative C balance. We show that soil C losses increase when soil microbes are nutrient limited. Results highlight the need for a better understanding of microbial mechanisms involved in the complex relationship between C input and soil C sequestration. We conclude that energy available to soil microbes and microbial competition are important determinants of soil C decomposition.
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Citations
Plant carbon components derived from maize straw influence priming processes in two mollisols.
TL;DR: In this paper, the effect of different types of plant carbon on the mineralization of the added carbon and of soil organic carbon (SOC) could contribute to understanding the priming effect.
5
Carbon and nutrient colimitations control the microbial response to fresh organic carbon inputs in soil at different depths
Lorène Siegwart,Gabin Piton,Christophe Jourdan,Clément Piel,J. Sauze,Soh Sugihara,Isabelle Bertrand +6 more
TL;DR: Fresh organic carbon inputs in soil at different depths interact with nutrient availability to control microbial activity, with topsoil C-limited and subsoil C- and N-colimited, influencing carbon balance and sequestration potential.
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•Dissertation
Fungal and bacterial contributions to decomposition in terrestrial and aquatic ecosystems
Margarida Soares
- 24 May 2019
TL;DR: In this article, the authors compared the bacterial and fungal contributions to decomposition by developing conversion factors to measure microbial growth in units of C and found that higher CUE was a result of low F:B in low mineral N and high pH soils, with no effect of OM quality.
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TL;DR: In this paper, the authors build a conceptual model of the priming effect based on the contradictory results available in the literature adopting the concept of nutritional competition, and they postulate that priming results from the competition for energy and nutrient acquisition between the microorganisms specialized in the decomposition of fresh organic matter and those feeding on polymerised SOM.
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M.R. Carter,B. A. Stewart +1 more
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TL;DR: In this article, the authors present an analysis of Soil organic matter storage in Agroecosystems. But their focus is on the storage of organic matter in Soil Fraction and Aggregates.
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