Separating the impact of climate change and human activities on the connection between meteorological and hydrological drought

IF 3.2 3区 地球科学 Q1 Environmental Science
Jianyu Fu, Bingjun Liu, Yang Lu, Yuling Chen, Fang Yang, Yong He, Wenhao Jia, Yun Zhang
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Abstract

Understanding the transition from meteorological to hydrological drought is essential for accurately predicting hydrological droughts. However, the factors driving this transition are intricate, and a comprehensive understanding of how direct human activities influence this shift in drought is lacking. In this study, we initially explored the spatiotemporal correlation between the occurrence of meteorological and hydrological droughts. Subsequently, we formulated multiple hydrological replenishment scenarios using the soil and water assessment tool (SWAT) model to assess the environmental impact of the transition from meteorological to hydrological droughts. The Xijiang River Basin (XRB), the primary tributary of the Pearl River basin, was selected as the study area. Our results identified 91 meteorological droughts in the XRB, and only 66 hydrological droughts from 1978 to 2018. The transition rate from meteorological to hydrological drought demonstrated large spatial variability, with a basin-average rate of 56% and the lowest transition rate of 45% in the headstream The transition from meteorological to hydrological drought was mostly rapid between November and December (~2 months), but can be prolonged during spring (about 3–5 months) and winter (around 7–9 months). Additionally, analysis of regeneration scenarios indicated that human activity has mitigated drought severity over recent decades. The primary driver affecting drought duration and frequency during the transition from meteorological to hydrological droughts shows conspicuous spatial disparities in densely populated areas. Although human activity significantly contributes to drought duration and severity compared to climate change during the transition in the headstream, its effects are more pronounced downstream in terms of drought duration and frequency. One plausible explanation is that increased water consumption downstream has considerably prolonged drought progression, whereas water management has counteractive effects on drought progression due to climate change in the headstream. Our findings offer valuable insights into the transition process from meteorological to hydrological droughts in the presence of extensive human activities.

Abstract Image

区分气候变化和人类活动对气象干旱和水文干旱之间联系的影响
了解从气象干旱到水文干旱的转变对于准确预测水文干旱至关重要。然而,驱动这一转变的因素错综复杂,目前还缺乏对人类活动如何直接影响干旱转变的全面了解。在本研究中,我们首先探讨了气象干旱和水文干旱发生的时空相关性。随后,我们利用水土评估工具(SWAT)模型制定了多种水文补给方案,以评估气象干旱向水文干旱转变对环境的影响。珠江流域的主要支流西江流域(XRB)被选为研究区域。我们的研究结果发现,1978 年至 2018 年期间,西江流域发生了 91 次气象干旱,而水文干旱只有 66 次。气象干旱向水文干旱的过渡率表现出较大的空间变异性,流域平均过渡率为 56%,而上游地区的过渡率最低,为 45%。气象干旱向水文干旱的过渡主要在 11 月至 12 月之间(约 2 个月),但在春季(约 3-5 个月)和冬季(约 7-9 个月)会延长。此外,对再生情景的分析表明,近几十年来人类活动减轻了干旱的严重程度。从气象干旱向水文干旱过渡期间,影响干旱持续时间和频率的主要驱动因素在人口稠密地区表现出明显的空间差异。虽然与气候变化相比,人类活动对上游干旱持续时间和严重程度的影响更大,但就干旱持续时间和频率而言,人类活动对下游的影响更为明显。一个合理的解释是,下游用水量的增加大大延长了干旱的持续时间,而水资源管理则对上游气候变化造成的干旱持续时间产生了反作用。我们的研究结果为了解在人类活动广泛存在的情况下从气象干旱到水文干旱的过渡过程提供了宝贵的见解。
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来源期刊
Hydrological Processes
Hydrological Processes 环境科学-水资源
CiteScore
6.00
自引率
12.50%
发文量
313
审稿时长
2-4 weeks
期刊介绍: Hydrological Processes is an international journal that publishes original scientific papers advancing understanding of the mechanisms underlying the movement and storage of water in the environment, and the interaction of water with geological, biogeochemical, atmospheric and ecological systems. Not all papers related to water resources are appropriate for submission to this journal; rather we seek papers that clearly articulate the role(s) of hydrological processes.
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