Increasing gross primary productivity under soil warming and wetting on the Tibetan Plateau

Environmental Research Letters Pub Date : 2024-01-25 DOI:10.1088/1748-9326/ad1d4f

Q-LearningJING Peng, Binghao Jia, Xin Lai, Longhuan Wang, Qifeng Huang

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Abstract

The soil freeze-thaw process has undergone significant changes on the Tibetan Plateau (TP) in the context of global change, resulting in the changes of soil physical and chemical properties, thereby affecting the vegetation phenology and photosynthesis through affecting the utilization capacity of CO2 and light by vegetation. However, little is known about how soil temperature (ST) and soil moisture (SM) affect the gross primary productivity (GPP) on the TP at different seasons and elevations. In this study, the spatiotemporal variation patterns of GPP, ST, and SM were analyzed based on the Community Land Model version 5.0 (CLM5.0) simulations in order to illustrate the impacts of ST and SM in surface (0–10 cm) and root zone soil (0–100 cm) on GPP between 1979 and 2020. The results showed that the CLM5.0-based GPP and ST were in good agreement with in situ observations. ST, SM and GPP increased at the rates of 0.04 °C a−1, 2.4 × 10−4mm3 mm−3 a−1, and 5.36 g C m−2 a−2, respectively. SM dominated the variations of GPP in winter (64.3%), while ST almost was the dominant factor in other periods, especially spring (99.9%) and autumn (94.7%). The explanatory power of ST and SM for GPP increased with elevation, especially for ST. The relative contributions of ST and SM to GPP at different time scales in root zone soil were similar to those in surface soil. This study provided a new understanding of how soil freeze-thaw affected GPP changes on the TP in the context of the intensification of warming and humidification.

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青藏高原土壤增温增湿条件下初级生产力总值的提高

在全球变化的背景下，青藏高原的土壤冻融过程发生了显著变化，导致土壤物理和化学性质的改变，进而通过影响植被对二氧化碳和光的利用能力来影响植被的物候和光合作用。然而，人们对不同季节和海拔高度下土壤温度（ST）和土壤湿度（SM）如何影响土壤初级生产力（GPP）知之甚少。本研究基于社区土地模型 5.0 版（CLM5.0）模拟分析了 GPP、ST 和 SM 的时空变化规律，以说明 1979 至 2020 年间表层（0-10 厘米）和根带土壤（0-100 厘米）中的 ST 和 SM 对 GPP 的影响。结果表明，基于 CLM5.0 的 GPP 和 ST 与实地观测结果非常吻合。ST、SM 和 GPP 的增长率分别为 0.04 °C a-1、2.4 × 10-4mm3 mm-3 a-1 和 5.36 g C m-2 a-2。在冬季，SM 主导了 GPP 的变化（64.3%），而在其他时期，尤其是春季（99.9%）和秋季（94.7%），ST 几乎是主导因素。ST 和 SM 对 GPP 的解释能力随着海拔的升高而增强，尤其是 ST。在不同时间尺度上，根区土壤中 ST 和 SM 对 GPP 的相对贡献与表层土壤相似。该研究为在气候变暖和湿度增加的背景下土壤冻融如何影响TP的GPP变化提供了新的认识。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Environmental Research Letters

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