Twenty Years of Progress, Challenges, and Opportunities in Measuring and Understanding Soil Respiration

Soil respiration (Rs), the soil‐to‐atmosphere flux of CO2, is a dominant but uncertain part of the carbon cycle, even after decades of study. This review focuses on progress in understanding Rs from laboratory incubations to global estimates. We survey key developments of in situ ecosystem‐scale Rs...

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Bibliographic Details
Published in:Journal of geophysical research. Biogeosciences 2024-02, Vol.129 (2), p.n/a
Main Authors: Bond‐Lamberty, Ben, Ballantyne, Ashley, Berryman, Erin, Fluet‐Chouinard, Etienne, Jian, Jinshi, Morris, Kendalynn A., Rey, Ana, Vargas, Rodrigo
Format: Article
Language:English
Subjects:
Atmosphere
Atmospheric models
Carbon cycle
Carbon dioxide
Climate change
Ecosystems
Environmental changes
Environmental effects
ENVIRONMENTAL SCIENCES
Estimates
Experiments
Fluctuations
Kinetics
Land use
Machine learning
Meta-analysis
Natural phenomena
Plant roots
Respiration
review
Soil
Soil dynamics
soil respiration
Soils
Substrates
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Summary:Soil respiration (Rs), the soil‐to‐atmosphere flux of CO2, is a dominant but uncertain part of the carbon cycle, even after decades of study. This review focuses on progress in understanding Rs from laboratory incubations to global estimates. We survey key developments of in situ ecosystem‐scale Rs observations and manipulations, synthesize Rs meta‐analyses and global flux estimates, and discuss the most compelling challenges and opportunities for the future. Increasingly sophisticated lab experiments have yielded insights into the interaction among heterotrophic respiration, substrate supply, and enzymatic kinetics, and extended incubation‐based analyses across space and time. Observational and manipulative field‐based experiments have used improved measurement approaches to deepen our understanding of the integrated effects of environmental change and disturbance on Rs. Freely‐available observational databases have enabled meta‐analyses and studies probing the magnitude of, and constraints on, the global Rs flux. Key challenges for the field include expanding Rs measurements, experiments, and opportunities to under‐represented communities and ecosystems; reconciling independent estimates of global respiration fluxes and trends; testing and leveraging the power of machine learning and process‐based models, both independently and in conjunction with each other; and continuing the field's tradition of using novel experiments to explore diverse mechanisms and ecosystems. Plain Language Summary “Soil respiration” refers to the flow of carbon dioxide, mostly generated by plant roots and microbes, from the soil to the atmosphere. This flux is large and highly uncertain, and understanding it has significant implications for our ability to predict the effects of land use and climate change. This review summarizes advances, insights, and challenges in soil respiration science. It examines laboratory approaches and findings; documents changes in how researchers measure and understand soil respiration in the natural world; and describes efforts to estimate the global dynamics of soil respiration from openly‐available databases of observations. We conclude by discussing the most compelling challenges and opportunities for the future. Key Points Recent decades have seen large advances in measurement methods, experimental approaches, and data availability in soil respiration science Lab and field‐based experiments have improved our understanding of the integrated effec
ISSN:2169-8953
2169-8961
DOI:10.1029/2023JG007637