摘要
Adjustments in foliar photoprotective pigments are crucial for plant adaptation to harsh environments,serving as indicators of environmental stress.However,understanding when and where these adjustments occur across diverse biomes remains unclear due to challenges in large-scale observation.Here,we propose a novel approach to assess dynamics in photoprotective pigments at the canopy level using a new index derived from spaceborne optical sensors.This approach generates a global map depicting the daily mean shortwave radiation threshold at which adjustments typically occur under prevailing climatic conditions.The global average of this threshold is 262±50 W m⁻2,with lower values at high latitudes and peaks near 40in both hemispheres.Temperature exerts a stronger influence on this latitudinal pattern than humidity.Future projections suggest a decrease in this threshold over northern high latitudes,implying exacerbated vulnerability under identical radiation levels due to negative warming responses.Based on this threshold,a high-stress zone around 60N is identified and is predicted to shift southward in the future.These findings bridge critical gaps in photoprotection research and offer a new perspective on understanding the biogeochemical cycles of global ecosystems.This framework can also enhance our ability to predict the fate of diverse ecosystems under future climate.
基金
cofunded by the Innovative Research Program of the International Research Center of Big Data for Sustainable Development Goals(CBAS2022IRP03)
the National Science Foundation of China(42276241)
the International Joint Research Project of Chinese Academy of Sciences(183611KYSB20200059).
