Litcius/Paper detail

Water Budgets Control the Resilience of Large‐Scale Ecological Restoration

Hang Xu, Jianzhuang Pang, Jiquan Chen, Xiaohua Wei, Xiaoyun Wu, Wenxu Cao, Zeyu Yuan, Ge Sun, Yang Xu, Qin Zhang, Zhiqiang Zhang

2025Geophysical Research Letters7 citationsDOIOpen Access PDF

Abstract

Abstract Large‐scale ecological restoration is a key nature‐based solution to environmental challenges. However, the resilience of such initiatives is debated due to increasing water consumption. This study examined China's Three‐North Shelterbelt Forest Program, the world's largest ecological restoration project, to assess how water regulated vegetation resilience from 2001 to 2022 and projected future vegetation suitability by integrating meteorological observations, remote sensing data, and Global Circulation Models. We found that approximately 48.2% of vegetation, particularly forests, experienced declining resilience despite greening. Resilience increased with productivity within water resources carrying capacity but decreased when exceeded. Forest resilience peaked when precipitation was fully utilized, whereas grassland resilience was lowest at this equilibrium. By 2050, 1.8% of the area is projected to face degradation risks, with an additional 11.1% at potential risk under the SSP2‐4.5 scenario. Overall, our findings highlight the necessity of integrating water resources constraints into ecological restoration strategies for sustained effectiveness.

Topics & Concepts

Resilience (materials science)Environmental scienceScale (ratio)Restoration ecologyEcologyEnvironmental resource managementGeographyBiologyPhysicsThermodynamicsCartographyEcosystem dynamics and resilienceLand Use and Ecosystem ServicesEcology and Vegetation Dynamics Studies