Matrix Approach to Land Carbon Cycle Modeling

Land ecosystems contribute to climate change mitigation by taking up approximately 30% of anthropogenically emitted carbon. However, estimates of the amount and distribution of carbon uptake across the world's ecosystems or biomes display great uncertainty. The latter hinders a full understandi...

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Bibliographic Details
Published in:Journal of advances in modeling earth systems 2022-07, Vol.14 (7), p.n/a
Main Authors: Luo, Yiqi, Huang, Yuanyuan, Sierra, Carlos A., Xia, Jianyang, Ahlström, Anders, Chen, Yizhao, Hararuk, Oleksandra, Hou, Enqing, Jiang, Lifen, Liao, Cuijuan, Lu, Xingjie, Shi, Zheng, Smith, Benjamin, Tao, Feng, Wang, Ying‐Ping
Format: Article
Language:English
Subjects:
Afforestation
Annan geovetenskap och miljövetenskap
Anthropogenic factors
Big Data
biogeochemistry
Carbon
Carbon capture and storage
Carbon cycle
Carbon cycle models
Carbon exchange
Carbon sequestration
Carbon sinks
Carbon uptake
Climate change
Climate change mitigation
Climate Research
Data assimilation
Decomposition
dynamical equation
Earth and Related Environmental Sciences
Ecosystems
ENVIRONMENTAL SCIENCES
Geovetenskap och miljövetenskap
Klimatforskning
Meteorologi och atmosfärforskning
Meteorology and Atmospheric Sciences
Mitigation
Modelling
Natural Sciences
Naturvetenskap
Ordinary differential equations
Other Earth and Related Environmental Sciences
Residence time
Sensitivity analysis
Storage capacity
Storage conditions
terrestrial ecosystems
Uncertainty
uncertainty analysis
Uptake
Vegetation
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Summary:Land ecosystems contribute to climate change mitigation by taking up approximately 30% of anthropogenically emitted carbon. However, estimates of the amount and distribution of carbon uptake across the world's ecosystems or biomes display great uncertainty. The latter hinders a full understanding of the mechanisms and drivers of land carbon uptake, and predictions of the future fate of the land carbon sink. The latter is needed as evidence to inform climate mitigation strategies such as afforestation schemes. To advance land carbon cycle modeling, we have developed a matrix approach. Land carbon cycle models use carbon balance equations to represent carbon exchanges among pools. Our approach organizes this set of equations into a single matrix equation without altering any processes of the original model. The matrix equation enables the development of a theoretical framework for understanding the general, transient behavior of the land carbon cycle. While carbon input and residence time are used to quantify carbon storage capacity at steady state, a third quantity, carbon storage potential, integrates fluxes with time to define dynamic disequilibrium of the carbon cycle under global change. The matrix approach can help address critical contemporary issues in modeling, including pinpointing sources of model uncertainty and accelerating spin‐up of land carbon cycle models by tens of times. The accelerated spin‐up liberates models from the computational burden that hinders comprehensive parameter sensitivity analysis and assimilation of observational data to improve model accuracy. Such computational efficiency offered by the matrix approach enables substantial improvement of model predictions using ever‐increasing data availability. Overall, the matrix approach offers a step change forward for understanding and modeling the land carbon cycle. Plain Language Summary Earth system models (ESMs) are the tools we have to predict future states of climate and ecosystems. However, land carbon cycle models, a critical component of ESMs, are highly diverse in both structures and predictions, hindering our ability to obtain consistent future projections. The latter is needed as part of the evidence base to inform climate change mitigation strategies. This paper describes a matrix approach that unifies land carbon cycle models in one matrix form. The matrix models offer consistency and simplicity in structure that make the models analytically tractable. In addition, the
ISSN:1942-2466
1942-2466
DOI:10.1029/2022MS003008