Climate-warming-driven changes in the cryosphere and their impact on groundwater–surface-water interactions in the Heihe River basin

IF 5.7 1区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY Hydrology and Earth System Sciences Pub Date : 2023-07-26 DOI:10.5194/hess-27-2763-2023
Amanda Triplett, L. Condon
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Abstract

Abstract. The Heihe River basin in northwest China depends heavily on both anthropogenic and natural storage (e.g., surface reservoirs, rivers and groundwater) to support economic and environmental functions. The Qilian Mountain cryosphere in the upper basin is integral to recharging these storage supplies. It is well established that climate warming is driving major shifts in high-elevation water storage through loss of glaciers and permafrost. However, the impacts on groundwater–surface-water interactions and water supply in corresponding lower reaches are less clear. We built an integrated hydrologic model of the middle basin, where most water usage occurs, in order to explore the hydrologic response to the changing cryosphere. We simulate the watershed response to loss of glaciers (glacier scenario), advanced permafrost degradation (permafrost scenario), both of these changes simultaneously (combined scenario) and projected temperature increases in the middle basin (warming scenario) by altering streamflow inputs to the model to represent cryosphere-melting processes, as well as by increasing the temperature of the climate forcing data. Net losses to groundwater storage in the glacier scenario and net gains in the permafrost and combined scenarios show the potential of groundwater exchanges to mediate streamflow shifts. The result of the combined scenario also shows that permafrost degradation has more of an impact on the system than glacial loss. Seasonal differences in groundwater–surface-water partitioning are also evident. The glacier scenario has the highest fraction of groundwater in terms of streamflow in early spring. The permafrost and combined scenarios meanwhile have the highest fraction of streamflow infiltration in late spring and summer. The warming scenario raises the temperature of the combined scenario by 2 ∘C. This results in net groundwater storage loss, a reversal from the combined scenario. Large seasonal changes in evapotranspiration and stream network connectivity relative to the combined scenario show the potential for warming to overpower changes resulting from streamflow. Our results demonstrate the importance of understanding the entire system of groundwater–surface-water exchanges to assess water resources under changing climatic conditions. Ultimately, this analysis can be used to examine the cascading impact of climate change in the cryosphere on the resilience of water resources in arid basins downstream of mountain ranges globally.
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气候变暖驱动的黑河流域冰冻圈变化及其对地下水-地表水相互作用的影响
摘要中国西北黑河流域在很大程度上依赖于人为和自然储存(如地表水库、河流和地下水)来支持经济和环境功能。盆地上部的祁连山冰冻圈是补给这些储备物资的必要条件。众所周知,气候变暖正在通过冰川和永久冻土的消失,推动高海拔地区水资源储存的重大变化。然而,对地下水-地表水相互作用和相应下游供水的影响尚不清楚。为了探索冰冻圈变化对流域水文的响应,我们在流域中部建立了一个综合水文模型。我们模拟了流域对冰川损失(冰川情景)、永久冻土退化(永久冻土情景)、这两种变化同时发生(联合情景)的响应,并通过改变模型的流量输入来表示冰冻圈融化过程,以及通过增加气候强迫数据的温度来预测盆地中部的温度升高(变暖情景)。冰川情景下地下水储存的净损失以及永久冻土和综合情景下的净收益显示了地下水交换调节水流变化的潜力。综合情景的结果还表明,多年冻土退化对系统的影响大于冰川损失。地下水-地表水分配的季节差异也很明显。就早春的水流而言,冰川情景中地下水的比例最高。而在春末和夏季,多年冻土和混合情景的径流入渗比例最高。变暖情景使上述两种情景的温度增加2°C。这导致地下水储存的净损失,与综合情况相反。相对于综合情景,蒸散和河流网络连通性的大季节变化表明,变暖有可能压倒由河流引起的变化。我们的研究结果表明,了解地下水-地表水交换的整个系统对于评估气候条件下水资源的重要性。最终,该分析可用于检验冰冻圈气候变化对全球山脉下游干旱盆地水资源恢复力的级联影响。
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来源期刊
Hydrology and Earth System Sciences
Hydrology and Earth System Sciences 地学-地球科学综合
CiteScore
10.10
自引率
7.90%
发文量
273
审稿时长
15 months
期刊介绍: Hydrology and Earth System Sciences (HESS) is a not-for-profit international two-stage open-access journal for the publication of original research in hydrology. HESS encourages and supports fundamental and applied research that advances the understanding of hydrological systems, their role in providing water for ecosystems and society, and the role of the water cycle in the functioning of the Earth system. A multi-disciplinary approach is encouraged that broadens the hydrological perspective and the advancement of hydrological science through integration with other cognate sciences and cross-fertilization across disciplinary boundaries.
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