Carbon Management (Sep 2020)

Differentiating biological and chemical factors of top and deep soil carbon sequestration in semi-arid tropical Inceptisol: an outcome of structural equation modeling

  • Avijit Ghosh,
  • Amit K. Singh,
  • Sunil Kumar,
  • M. C. Manna,
  • Ranjan Bhattacharyya,
  • Rajesh Agnihortri,
  • Sanjay K. Singh Gahlaud,
  • Manjanagouda S. Sannagoudar,
  • Kamini Gautam,
  • R. V. Kumar,
  • Suresh K. Chaudhari

DOI
https://doi.org/10.1080/17583004.2020.1796143
Journal volume & issue
Vol. 11, no. 5
pp. 441 – 453

Abstract

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Though soils sequester large amounts of carbon (C), variations in physical and chemical characteristics of top and deep layers necessitate the study of factors governing topsoil and deep soil C sequestration to predict land-use changes to alleviate climate change. Land-use systems involving pasture, trees, trees pasture and fallow were considered. The upper soil (0–15 cm) had ∼12, 34 and 59% higher microbial biomass C than the 15–30, 30–45 and 45–60 cm layers, respectively. Fluorescein diacetate (FDA) and dehydrogenase activities had similar trends. Across the land uses, topsoil layers had ∼17% lower silt + clay (s + c) content than deep layers. Amorphous iron content significantly increased with soil depth. In the top two soil layers, s + c accounted for ∼19–30% of total soil organic carbon (SOC); in the next two layers s + c could store >30% of total SOC. Stepwise regression analysis revealed FDA to be the most significant biological driver for SOC sequestration. Structural equation modeling showed that biological factors controlled C sequestration in topsoil layers, while s + c and amorphous iron were the major factors of C sequestration in deep layers. Current land uses are largely deficient of SOC and have the potential to store an additional22 Mg CO2e per ha.

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