环境科学
生态系统
土壤水分
土壤质地
含水量
蒸腾作用
陆地生态系统
土壤科学
植被(病理学)
蒸汽压差
生态水文学
水文学(农业)
生态学
光合作用
地质学
生物
植物
病理
医学
岩土工程
作者
Fabian Wankmüller,Louis Delval,Peter Lehmann,Martin Baur,Andrea Cecere,Sebastian Wolf,Dani Or,Mathieu Javaux,Andrea Carminati
出处
期刊:Nature
[Nature Portfolio]
日期:2024-10-23
卷期号:635 (8039): 631-638
被引量:122
标识
DOI:10.1038/s41586-024-08089-2
摘要
Low soil moisture and high vapour pressure deficit (VPD) cause plant water stress and lead to a variety of drought responses, including a reduction in transpiration and photosynthesis1,2. When soils dry below critical soil moisture thresholds, ecosystems transition from energy to water limitation as stomata close to alleviate water stress3,4. However, the mechanisms behind these thresholds remain poorly defined at the ecosystem scale. Here, by analysing observations of critical soil moisture thresholds globally, we show the prominent role of soil texture in modulating the onset of ecosystem water limitation through the soil hydraulic conductivity curve, whose steepness increases with sand fraction. This clarifies how ecosystem sensitivity to VPD versus soil moisture is shaped by soil texture, with ecosystems in sandy soils being relatively more sensitive to soil drying, whereas ecosystems in clayey soils are relatively more sensitive to VPD. For the same reason, plants in sandy soils have limited potential to adjust to water limitations, which has an impact on how climate change affects terrestrial ecosystems. In summary, although vegetation-atmosphere exchanges are driven by atmospheric conditions and mediated by plant adjustments, their fate is ultimately dependent on the soil.
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