固碳
生态系统
营养物
磷
环境科学
农学
人类受精
土壤水分
碳循环
土壤碳
森林生态学
生物利用度
气候变化
光合作用
生物量(生态学)
碳纤维
生态学
环境化学
全球变化
化学
营养循环
陆地生态系统
适应
生态系统生态学
农林复合经营
生态系统服务
土壤肥力
土壤有机质
作者
B. Wang,He Lyu,Xueqian Zhang,Mingkai Jiang,Belinda E. Medlyn,David Wårlind,Jürgen Knauer,Katrin Fleischer,Daniel S. Goll,Stefan Olin,X. B. Yang,Lin Yu,Sönke Zaehle,Haicheng Zhang,Kristian Schufft,Kristine Y. Crous,Yolima Carrillo,Catriona A. Macdonald,Ian C. Anderson,Matthias M. Boer
标识
DOI:10.1073/pnas.2516152123
摘要
The capacity of nutrient-limited forests to enhance carbon (C) sequestration under elevated CO 2 (eCO 2 ) remains a critical uncertainty in C cycle modeling. While existing evidence suggests that low phosphorus (P) bioavailability may constrain CO 2 fertilization effects on plant growth, the extent to which this limitation modulates ecosystem responses to eCO 2 in forests adapted to P-deficient soils remains poorly understood. Here, using eight P-enabled models, we simulated the magnitudes and mechanisms through which P bioavailability interacts with eCO 2 , emulating an ecosystem-scale P enrichment experiment at a P-limited Eucalyptus forest undergoing long-term Free-Air CO 2 Enrichment. While models predicted pronounced P effects on tree growth, P enrichment unexpectedly did not increase the CO 2 effects on tree growth and ecosystem C sequestration. Models prioritized either CO 2 -driven or P-driven growth, but rarely both. This tradeoff emerged due to model-specific assumptions on 1) partitioning of the extra P in soil labile versus nonlabile pools; 2) plant photosynthetic acclimation to P deficiency; 3) C and nutrient use strategies regulating plant size and allocation; and 4) microbial-driven soil decomposition processes. By generating divergent yet biologically plausible outcomes, these predictions establish critical testable hypotheses for empirical research and highlight multiple P-related pathways that may influence the future land C sink.
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