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Toward more realistic projections of soil carbon dynamics by Earth system models

Author

Luo, Yiqi
Ahlstrom, Anders
Allison, Steven D.
Batjes, Niles H.
Brovkin, Victor
Carvalhais, Nuno
Chappell, Adrian
Ciais, Philippe
Davidson, Eric A.
Finzi, Adrien C.
Georgiou, Katerina
Guenet, Bertrand
Hararuk, Oleksandra
Harden, Jennifer W.
He, Yujie
Hopkins, Francesca
Jiang, Lifen
Koven, Charlie
Jackson, Robert B.
Jones, Chris D.
Lara, Mark J.
Liang, Junyi
McGuire, A. David
Parton, William
Peng, Changhui
Randerson, James T.
Salazar, Alejandro
Sierra, Carlos A.
Smith, Mathew J.
Tian, Hanqin
Todd-Brown, Katherine E.O.
Torn, Margaret
van Groenigen, Kees Jan
Wang, Ying Ping
West, Tristram O.
Wei, Yaxing
Wieder, William R
Xia, Jianyang
Xu, Xia
Xu, Xiaofeng
Zhou, Tao
0000-0002-1806-4091

Abstract

Soil carbon (C) is a critical component of Earth system models (ESMs), and its diverse representations are a major source of the large spread across models in the terrestrial C sink from the third to fifth assessment reports of the Intergovernmental Panel on Climate Change (IPCC). Improving soil C projections is of a high priority for Earth system modeling in the future IPCC and other assessments. To achieve this goal, we suggest that (1) model structures should reflect real-world processes, (2) parameters should be calibrated to match model outputs with observations, and (3) external forcing variables should accurately prescribe the environmental conditions that soils experience. First, most soil C cycle models simulate C input from litter production and C release through decomposition. The latter process has traditionally been represented by first-order decay functions, regulated primarily by temperature, moisture, litter quality, and soil texture. While this formulation well captures macroscopic soil organic C (SOC) dynamics, better understanding is needed of their underlying mechanisms as related to microbial processes, depth-dependent environmental controls, and other processes that strongly affect soil C dynamics. Second, incomplete use of observations in model parameterization is a major cause of bias in soil C projections from ESMs. Optimal parameter calibration with both pool-and flux-based data sets through data assimilation is among the highest priorities for near-term research to reduce biases among ESMs. Third, external variables are represented inconsistently among ESMs, leading to differences in modeled soil C dynamics. We recommend the implementation of traceability analyses to identify how external variables and model parameterizations influence SOC dynamics in different ESMs. Overall, projections of the terrestrial C sink can be substantially improved when reliable data sets are available to select the most representative model structure, constrain parameters, and prescribe forcing fields.