Increased atmospheric water stress on gross primary productivity during flash droughts over China from 1961 to 2022

IF 6.1 1区 地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES Weather and Climate Extremes Pub Date : 2024-03-28 DOI:10.1016/j.wace.2024.100667
Xiazhen Xi , Miaoling Liang , Xing Yuan
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引用次数: 0

Abstract

Flash droughts threaten ecosystems substantially because of the fast onset and low predictability. Soil and atmospheric water stress are two main factors reducing ecosystem productivity during flash droughts. However, the long-term trends in the soil and atmospheric water stress on vegetation during flash droughts are unclear. By conducting long-term land surface model simulations, this study investigated the impact of atmospheric and soil water stress on gross primary productivity (GPP) during flash droughts and hot periods of flash droughts, as well as the long-term changes in water stress from 1961 to 2022 over China. The areas dominated by soil and atmospheric stress were 65.2% and 19.9% during flash droughts, respectively. During the hot periods of flash droughts, the areas dominated by atmospheric water stress were raised to 39.4%, and the areas dominated by soil water stress were reduced to 48.7%. During 1961–2022, the frequency, intensity, and duration of flash droughts all showed significant upward trends (p < 0.05) over China. Meanwhile, soil water stress on GPP decreased significantly (p < 0.05), but the atmospheric water stress increased significantly (p < 0.05). Correspondingly, the areas dominated by soil water stress decreased at 0.8%/decade, while the areas dominated by atmospheric water stress rose at 1.6%/decade during hot periods of flash droughts. With sensitivity simulations, we found that the water stress was weakened in the North China plain under irrigated conditions, but the trend was consistent with non-irrigated conditions over China. Our study indicated the importance of atmospheric moisture stress on vegetation productivity during flash droughts under climate warming.

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1961 年至 2022 年中国上空山洪暴发干旱期间大气水压力增加对总初级生产力的影响
由于山洪暴发迅速且可预测性低,山洪暴发对生态系统造成了严重威胁。土壤和大气水分胁迫是闪旱期间降低生态系统生产力的两个主要因素。然而,山洪灾害期间土壤和大气对植被的水分胁迫的长期趋势尚不清楚。本研究通过长期地表模型模拟,研究了闪旱和闪旱高温期大气和土壤水分胁迫对总初级生产力(GPP)的影响,以及1961-2022年中国水胁迫的长期变化。在山洪灾害期间,受土壤和大气胁迫影响的面积分别为 65.2%和 19.9%。在山洪灾害的高温期,大气水胁迫主导面积增加到 39.4%,土壤水胁迫主导面积减少到 48.7%。1961-2022年间,中国山洪灾害的频率、强度和持续时间均呈显著上升趋势(p <0.05)。同时,土壤水分胁迫对 GPP 的影响显著降低(p <0.05),但大气水分胁迫显著增加(p <0.05)。相应地,在高温干旱期间,土壤水分胁迫主导面积以 0.8%/十年的速度减少,而大气水分胁迫主导面积以 1.6%/十年的速度增加。通过敏感性模拟,我们发现在灌溉条件下,华北平原的水分胁迫有所减弱,但这一趋势与中国各地的非灌溉条件一致。我们的研究表明,在气候变暖条件下,大气水分胁迫对闪旱期间植被生产力的影响非常重要。
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来源期刊
Weather and Climate Extremes
Weather and Climate Extremes Earth and Planetary Sciences-Atmospheric Science
CiteScore
11.00
自引率
7.50%
发文量
102
审稿时长
33 weeks
期刊介绍: Weather and Climate Extremes Target Audience: Academics Decision makers International development agencies Non-governmental organizations (NGOs) Civil society Focus Areas: Research in weather and climate extremes Monitoring and early warning systems Assessment of vulnerability and impacts Developing and implementing intervention policies Effective risk management and adaptation practices Engagement of local communities in adopting coping strategies Information and communication strategies tailored to local and regional needs and circumstances
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