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Ecological restoration enhances dryland carbon stock by reducing surface soil carbon loss due to wind erosion

Jian Song, Shiqiang Wan, Kesheng Zhang, Songbai Hong, Jianyang Xia, Shilong Piao, Ying‐Ping Wang, Jiquan Chen, Dafeng Hui, Yiqi Luo, Shuli Niu, Jingyi Ru, Hao Xu, Mengmei Zheng, Weixing Liu, Haidao Wang, Min Tan, Zhenxing Zhou, Jiayin Feng, Xueli Qiu

2024Proceedings of the National Academy of Sciences28 citationsDOIOpen Access PDF

Abstract

Enhancing terrestrial carbon (C) stock through ecological restoration, one of the prominent approaches for natural climate solutions, is conventionally considered to be achieved through an ecological pathway, i.e., increased plant C uptake. By conducting a comprehensive regional survey of 4279 1 × 1 m 2 plots at 517 sites across China’s drylands and a 13-y manipulative experiment in a semiarid grassland within the same region, we show that greater soil and ecosystem C stocks in restored than degraded lands result predominantly from decreased surface soil C loss via suppressed wind erosion. This biophysical pathway is always overlooked in model evaluation of land-based C mitigation strategies. Surprisingly, stimulated plant growth plays a minor role in regulating C stocks under ecological restoration. In addition, the overall enhancement of C stocks in the restored lands increases with both initial degradation intensity and restoration duration. At the national scale, the rate of soil C accumulation (7.87 Tg C y −1 ) due to reduced wind erosion and surface soil C loss under dryland restoration is equal to 38.8% of afforestation and 56.2% of forest protection in China. Incorporating this unique but largely missed biophysical C-conserving mechanism into land surface models will greatly improve global assessments of the potential of land restoration for mitigating climate change.

Topics & Concepts

Environmental scienceSoil carbonAeolian processesCarbon fibersCarbon sequestrationErosionSoil lossRestoration ecologyWater erosionStock (firearms)Soil scienceHydrology (agriculture)EcologyCarbon dioxideGeologySoil waterGeographyGeotechnical engineeringGeomorphologyMaterials scienceBiologyArchaeologyComposite numberComposite materialAeolian processes and effectsSoil erosion and sediment transportSoil Carbon and Nitrogen Dynamics
Ecological restoration enhances dryland carbon stock by reducing surface soil carbon loss due to wind erosion | Litcius