Quantifying the overlooked groundwater component in the water budget of a shallow soda lake in Hungary amidst climate change concerns

IF 4.7 2区 地球科学 Q1 WATER RESOURCES
Petra Baják , András Csepregi , Péter Szabó , Máté Chappon , Ádám Tóth , Katalin Hegedűs-Csondor , Anita Erőss
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引用次数: 0

Abstract

Study region

Lake Velence.

Study focus

Soda lakes are extreme habitats whose special hydrochemical characteristics can partly be explained by groundwater inflow. The relationship between groundwater and Lake Velence has never been properly investigated. A significant decrease in the lake’s level in recent years urged an evaluation of the components of the lake’s water budget, including groundwater as well. A 3D transient numerical groundwater flow simulation, using Visual MODFLOW, was performed between 1990 and 2021 to evaluate the lake’s relationship with groundwater and quantify the groundwater discharge into the lake. To assess future lake level changes until 2050, six lake level simulations were run based on three different regional climate models and two global warming scenarios (RCP2.6 and RCP8.5).

New hydrological insights for the region

Our results showed that groundwater inflow accounts for up to 12 % of the total annual inflow into Lake Velence. It has been numerically shown that precipitation and evaporation are the primary drivers of lake level changes, meaning that the variation of these two parameters will impact the lake’s future. As for the future lake level changes, the RCP2.6 scenario resulted in an increase of 11 cm, while the RCP8.5 scenario led to a decrease of 30 cm compared to the observed annual average lake level until 2050. Our results emphasize the importance of integrating soda lakes into topography-driven groundwater flow systems to develop climate change adaptation strategies.

在关注气候变化的同时量化匈牙利浅水苏打湖水量预算中被忽视的地下水成分
研究区域维伦茨湖。研究重点苏打湖是一种极端的栖息地,其特殊的水化学特征可部分归因于地下水的流入。地下水与 Velence 湖之间的关系从未得到过适当的研究。近年来湖水水位的大幅下降促使人们对包括地下水在内的湖水预算组成部分进行评估。在 1990 年至 2021 年期间,使用 Visual MODFLOW 进行了三维瞬态地下水流数值模拟,以评估湖泊与地下水的关系,并量化地下水排入湖泊的情况。我们的结果表明,地下水流入量占维纶斯湖年总流入量的 12%。数值显示,降水和蒸发是湖面变化的主要驱动力,这意味着这两个参数的变化将影响湖泊的未来。至于未来的湖面变化,RCP2.6 情景导致湖面上升 11 厘米,而 RCP8.5 情景则导致 2050 年前的观测年平均湖面下降 30 厘米。我们的研究结果强调了将苏打湖纳入地形驱动的地下水流系统以制定气候变化适应战略的重要性。
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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来源期刊
Journal of Hydrology-Regional Studies
Journal of Hydrology-Regional Studies Earth and Planetary Sciences-Earth and Planetary Sciences (miscellaneous)
CiteScore
6.70
自引率
8.50%
发文量
284
审稿时长
60 days
期刊介绍: Journal of Hydrology: Regional Studies publishes original research papers enhancing the science of hydrology and aiming at region-specific problems, past and future conditions, analysis, review and solutions. The journal particularly welcomes research papers that deliver new insights into region-specific hydrological processes and responses to changing conditions, as well as contributions that incorporate interdisciplinarity and translational science.
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