Soil carbon stock changes in tropical croplands are mainly driven by carbon inputs: A synthesis

Fujisaki Kenji, Chevallier Tiphaine, Chapuis-Lardy Lydie, Albrecht Alain, Razafimbelo-Andriamifidy Tantely, Masse Dominique, Ndour-Badiane Yacine, Chotte Jean-Luc. 2018. Soil carbon stock changes in tropical croplands are mainly driven by carbon inputs: A synthesis. Agriculture, Ecosystems and Environment, 259 : pp. 147-158.

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Quartile : Outlier, Sujet : AGRICULTURE, MULTIDISCIPLINARY / Quartile : Q1, Sujet : ECOLOGY / Quartile : Q2, Sujet : ENVIRONMENTAL SCIENCES

Abstract : Soil organic carbon (SOC) balance is an important component of the terrestrial carbon (C) budget. However, effect of cropland management changes on SOC dynamics has not been recently assessed in the tropics. Studies were compiled in the tropics where SOC stocks were measured in the topsoil (0–20 or 0–30 cm depth) after the adoption of management practices that are expected to enhance SOC stocks, including tillage reduction, crop rotation, exogenous organic amendments, restitution of crop residues, mineral amendments, and combinations of these practices. Random forest regression was used to identify the determinants of SOC accumulation rates (ΔSOC) depending on the climate, soil characteristics and changes in management practices. 214 cases were identified in 48 studies in 13 different countries. The average ΔSOC was 0.41 ± 0.03 Mg C ha−1 yr−1 (significantly greater than zero), for an average experiment duration of 13.6 ± 0.6 years. Although a large part of the variability remained unexplained due to methodological bias in the studies or a lack of relevant predictors. The strongest predictors of ΔSOC were C inputs, duration of the experiments, and the management practices, whereas neither soil characteristics (soil type, clay content, and initial SOC stock) nor climate variables (mean annual temperature and rainfall, aridity index) affected ΔSOC. The SOC accumulation rates increased linearly with C inputs, and the conversion rate of C inputs to SOC was 8.2 ± 0.8%. Given the competing uses of organic matter on many tropical farms, the benefits of using changes in management practices for climate change mitigation might be overrated. As ΔSOC decreased with the duration of the experiments, ΔSOC would probably be smaller if a period of 20 years were considered, as recommended by the IPCC guidelines. The management practice with the greatest ΔSOC was diversified crop rotation. Cropping systems where diverse practices were combined resulted in higher ΔSOC than individual practices such as reduced tillage and mineral fertilization on their own. The adoption of improved management practices that increase C inputs is still relevant for meeting the challenges of food security and adaptation to climate change.

Mots-clés Agrovoc : Changement climatique, Système de culture, Agroforesterie, évaluation des stocks de carbone, Fertilité du sol, Matière organique du sol

Mots-clés géographiques Agrovoc : Inde, Brésil, Madagascar, Niger, Zimbabwe, Mexique

Classification Agris : P33 - Soil chemistry and physics
U30 - Research methods
P35 - Soil fertility
F08 - Cropping patterns and systems

Champ stratégique Cirad : Axe 1 (2014-2018) - Agriculture écologiquement intensive

Auteurs et affiliations

  • Fujisaki Kenji, CIRAD-PERSYST-UPR AIDA (REU) - auteur correspondant
  • Chevallier Tiphaine, INRA (FRA)
  • Chapuis-Lardy Lydie, IRD (FRA)
  • Albrecht Alain, IRD (FRA)
  • Razafimbelo-Andriamifidy Tantely, Université d'Antananarivo (MDG)
  • Masse Dominique, IRD (FRA)
  • Ndour-Badiane Yacine, ISRA (SEN)
  • Chotte Jean-Luc, IRD (FRA)

Source : Cirad-Agritrop (

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