Soil respiration response to decade-long warming modulated by soil moisture in a boreal forest

Guopeng Liang; Artur Stefanski; William C. Eddy; Raimundo Bermudez; Rebecca A. Montgomery; Sarah E. Hobbie; Roy L. Rich; Peter B. Reich

doi:10.1038/s41561-024-01512-3

Soil respiration response to decade-long warming modulated by soil moisture in a boreal forest

Guopeng Liang
, Artur Stefanski
, William C. Eddy
, Raimundo Bermudez
, Rebecca A. Montgomery
, Sarah E. Hobbie
, Roy L. Rich
, Peter B. Reich

University of Minnesota Twin Cities
University of Illinois at Urbana-Champaign
Smithsonian Institution
Department of Forest Resources
Institute for Global Change Biology and School for Environment and Sustainability
University of Michigan, Ann Arbor

Research output: Contribution to journal › Article › peer-review

41 Citations (Scopus)

Abstract

The effects of long-term climate warming on soil respiration and its drivers remain unclear in forests, which store approximately 40% of global soil carbon. Here we conducted a climate change experiment for 13 years in forest plots planted with tree juveniles at two southern boreal forest sites. Treatments included simultaneous above- and below-ground warming (ambient, +1.7 Â°C and +3.3 Â°C) under different rainfall scenarios (100% and 60% of summer rainfall) and contrasting overstory canopy openness (open and closed). Soil respiration increased by 7% and 17% under +1.7 Â°C and +3.3 Â°C warming, respectively, averaged across all sites, treatments and years. These increases in respiration were higher than impacts per degree warming of the only two prior long-term, but soil-only, forest warming experiments. Moreover, warming effects on soil respiration varied significantly over time. Under almost all conditions, moist soil exhibited a greater increase in respiration in response to warming than dry soil. Our results suggest that a realistic range of anticipated conditions, including both above- and below-ground temperature and moisture, should be accounted for when predicting warming effects on soil respiration.

Original language	English
Pages (from-to)	905-911
Number of pages	7
Journal	Nature Geoscience
Volume	17
Issue number	9
DOIs	https://doi.org/10.1038/s41561-024-01512-3
Publication status	Published - 2024

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Publisher Copyright:
© The Author(s), under exclusive licence to Springer Nature Limited 2024.

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Cite this

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title = "Soil respiration response to decade-long warming modulated by soil moisture in a boreal forest",

abstract = "The effects of long-term climate warming on soil respiration and its drivers remain unclear in forests, which store approximately 40\% of global soil carbon. Here we conducted a climate change experiment for 13 years in forest plots planted with tree juveniles at two southern boreal forest sites. Treatments included simultaneous above- and below-ground warming (ambient, +1.7 {\^A}°C and +3.3 {\^A}°C) under different rainfall scenarios (100\% and 60\% of summer rainfall) and contrasting overstory canopy openness (open and closed). Soil respiration increased by 7\% and 17\% under +1.7 {\^A}°C and +3.3 {\^A}°C warming, respectively, averaged across all sites, treatments and years. These increases in respiration were higher than impacts per degree warming of the only two prior long-term, but soil-only, forest warming experiments. Moreover, warming effects on soil respiration varied significantly over time. Under almost all conditions, moist soil exhibited a greater increase in respiration in response to warming than dry soil. Our results suggest that a realistic range of anticipated conditions, including both above- and below-ground temperature and moisture, should be accounted for when predicting warming effects on soil respiration.",

author = "Guopeng Liang and Artur Stefanski and Eddy, \{William C.\} and Raimundo Bermudez and Montgomery, \{Rebecca A.\} and Hobbie, \{Sarah E.\} and Rich, \{Roy L.\} and Reich, \{Peter B.\}",

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AU - Stefanski, Artur

AU - Eddy, William C.

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AU - Montgomery, Rebecca A.

AU - Hobbie, Sarah E.

AU - Rich, Roy L.

AU - Reich, Peter B.

PY - 2024

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N2 - The effects of long-term climate warming on soil respiration and its drivers remain unclear in forests, which store approximately 40% of global soil carbon. Here we conducted a climate change experiment for 13 years in forest plots planted with tree juveniles at two southern boreal forest sites. Treatments included simultaneous above- and below-ground warming (ambient, +1.7 Â°C and +3.3 Â°C) under different rainfall scenarios (100% and 60% of summer rainfall) and contrasting overstory canopy openness (open and closed). Soil respiration increased by 7% and 17% under +1.7 Â°C and +3.3 Â°C warming, respectively, averaged across all sites, treatments and years. These increases in respiration were higher than impacts per degree warming of the only two prior long-term, but soil-only, forest warming experiments. Moreover, warming effects on soil respiration varied significantly over time. Under almost all conditions, moist soil exhibited a greater increase in respiration in response to warming than dry soil. Our results suggest that a realistic range of anticipated conditions, including both above- and below-ground temperature and moisture, should be accounted for when predicting warming effects on soil respiration.

AB - The effects of long-term climate warming on soil respiration and its drivers remain unclear in forests, which store approximately 40% of global soil carbon. Here we conducted a climate change experiment for 13 years in forest plots planted with tree juveniles at two southern boreal forest sites. Treatments included simultaneous above- and below-ground warming (ambient, +1.7 Â°C and +3.3 Â°C) under different rainfall scenarios (100% and 60% of summer rainfall) and contrasting overstory canopy openness (open and closed). Soil respiration increased by 7% and 17% under +1.7 Â°C and +3.3 Â°C warming, respectively, averaged across all sites, treatments and years. These increases in respiration were higher than impacts per degree warming of the only two prior long-term, but soil-only, forest warming experiments. Moreover, warming effects on soil respiration varied significantly over time. Under almost all conditions, moist soil exhibited a greater increase in respiration in response to warming than dry soil. Our results suggest that a realistic range of anticipated conditions, including both above- and below-ground temperature and moisture, should be accounted for when predicting warming effects on soil respiration.

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JO - Nature Geoscience

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ER -

Soil respiration response to decade-long warming modulated by soil moisture in a boreal forest

Abstract

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