Global warming changes biomass and C:N:P stoichiometry of different components in terrestrial ecosystems

Global warming has significantly affected terrestrial ecosystems. Biomass and C:N:P stoichiometry of plants and soil is crucial for enhancing plant productivity, improving human nutrition, and regulating biogeochemical cycles. However, the effect of warming on the biomass and C:N:P stoichiometry of...

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Bibliographic Details
Published in:Global change biology 2023-12, Vol.29 (24), p.7102-7116
Main Authors: Wan, Lingfan, Liu, Guohua, Cheng, Hao, Yang, Shishuai, Shen, Yu, Su, Xukun
Format: Article
Language:English
Subjects:
Biogeochemical cycle
Biogeochemical cycles
Biomass
Climate change
Components
ecological stoichiometry
ecosystem functioning
Ecosystems
Global warming
Human nutrition
Leaf litter
Leaves
Litter
Meta-analysis
Microorganisms
Nutrition
Plant biomass
Plant growth
Plants
Plants (botany)
Productivity
Ratios
Soil
Soils
Stems
Stoichiometry
Terrestrial ecosystems
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Summary:Global warming has significantly affected terrestrial ecosystems. Biomass and C:N:P stoichiometry of plants and soil is crucial for enhancing plant productivity, improving human nutrition, and regulating biogeochemical cycles. However, the effect of warming on the biomass and C:N:P stoichiometry of different components (plant, leaf, stem, root, litter, soil, and microbial biomass) in various terrestrial ecosystems remains uncertain. We conducted a comprehensive meta‐analysis to investigate the global patterns of biomass and C:N:P stoichiometry responses to warming, as well as interaction relationships based on 1399 paired observations from 105 warming studies. Results indicated that warming had a significant impact on various aspects of plant growth, including an increase in plant biomass (+16.55%), plant C:N ratio (+4.15%), leaf biomass (+16.78%), stem biomass (+23.65%), root biomass (+22.00%), litter C:N ratio (+9.54%) and soil C:N ratio (+5.64%). However, it also decreased stem C:P ratio (−23.34%), root C:P ratio (−12.88%), soil N:P ratio (−14.43%) and soil C:P ratio (−16.33%). The magnitude of warming was the primary drivers of changes of biomass and C:N:P stoichiometry. By establishing the general response curves of changes in biomass and C:N:P ratios with increasing temperature, we demonstrated that warming effect on plant, root, and litter biomass shifted from negative to positive, whereas that on leaf and stem biomass changed from positive to negative as temperature increased. Additionally, the effect of warming on root C:N ratio, root biomass, and microbial biomass N:P ratios shifted from positive to negative, whereas the effects on plant N:P, leaf N:P, leaf C:P, root N:P ratios, and microbial biomass C:N ratio changed from negative to positive with increasing temperature. Our research can help assess plant productivity and optimize ecosystem stoichiometry precisely in the context of global warming. Global warming has significantly affected biomass and C:N:P stoichiometry of plants and soil in terrestrial ecosystems. By a meta‐analysis, we found warming had a significant impact on various aspects of plant growth. The magnitude of warming was the primary drivers of changes of biomass and C:N:P stoichiometry. Moreover, we developed general response curves of biomass and C:N:P ratio with increasing temperature to explore the relationship. Our research can help assess plant productivity and optimize ecosystem stoichiometry precisely in the context of
ISSN:1354-1013
1365-2486
DOI:10.1111/gcb.16986