Latitudinal gradient and environmental drivers of soil organic carbon in permafrost regions of the Headwater Area of the Yellow River

Latitudinal gradient and environmental drivers of soil organic carbon in permafrost regions of the Headwater Area of the Yellow River

Abstract Understanding soil organic carbon (SOC) distribution and its environmental controls in permafrost regions is essential for achieving carbon neutrality and mitigating climate change. This study examines the spatial pattern of SOC and its drivers in the Headwater Area of the Yellow River (HAY...

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Bibliographic Details
Main Authors: Mingxin Yang, Shizhen Li, Shouxin Wang, Qingdongzhi Huang, Qi Shen, Yanbin Kang, Mingming Shi, Yafei Zhang, Dongliang Luo
Format: Article
Language:English
Published: Springer 2025-06-01
Series:Carbon Neutrality
Subjects:
Soil organic carbon (SOC)
Permafrost degradation
Alpine ecosystems
Headwater Area of the Yellow River
Online Access:https://doi.org/10.1007/s43979-025-00130-1
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Summary:Abstract Understanding soil organic carbon (SOC) distribution and its environmental controls in permafrost regions is essential for achieving carbon neutrality and mitigating climate change. This study examines the spatial pattern of SOC and its drivers in the Headwater Area of the Yellow River (HAYR), northeastern Qinghai-Xizang Plateau (QXP), a region highly susceptible to permafrost degradation. Field investigations at topsoils of 86 sites over three summers (2021–2023) provided data on SOC, vegetation structure, and soil properties. Moreover, the spatial distribution of key permafrost parameters was simulated: temperature at the top of permafrost (TTOP), active layer thickness (ALT), and maximum seasonal freezing depth (MSFD) using the TTOP model and Stefan Equation. Results reveal a distinct latitudinal SOC gradient (high south, low north), primarily mediated by vegetation structure, soil properties, and permafrost parameters. Vegetation coverage and above-ground biomass showed positive correlation with SOC, while soil bulk density (SBD) exhibited a negative correlation. Climate warming trends resulted in increased ALT and TTOP. Random Forest analysis identified SBD as the most important predictor of SOC variability, which explains 38.20% of the variance, followed by ALT and vegetation coverage. These findings likely enhance the understanding of carbon storage controls in vulnerable alpine permafrost ecosystems and provide insights to mitigate carbon release under climate change.
ISSN:2788-8614
2731-3948

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