Changes in seasonality of groundwater level fluctuations in a temperate-cold climate transition zone

IF 3.1 Q2 GEOSCIENCES, MULTIDISCIPLINARY
Michelle Nygren , Markus Giese , Bjørn Kløve , Ezra Haaf , Pekka M. Rossi , Roland Barthel
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引用次数: 38

Abstract

In cold (i.e. boreal, subarctic, snowy) climate zones, dynamic groundwater storage is greatly affected by the timing and amount of snowmelt. With global warming, cold climates in the northern hemisphere will transition to temperate. As temperatures rise, the dominant type of precipitation will change from snow to rain in winter. Further, the growing season is prolonged. This has a direct impact on the aquifer recharge pattern. However, little is known about the effect of changing annual recharge regimes on groundwater storage.

The present work deduces the impact of shifting climate zones on groundwater storage by evaluating the effect of climate seasonality on intra-annual hydraulic head fluctuations. The work compares intra-annual hydraulic head fluctuations in a temperate-cold climate transition zone (Fennoscandia) from two different periods (1980–1989, 2001–2010). This is done by associating rising vs. declining hydraulic heads with hydrometeorology.

Due to the northwards migration of the temperate climate zone, there is a shift in seasonality between the two periods. This has a negative impact on groundwater levels, which are significantly lower in 2001–2010, particularly near the climate transition zone. The results demonstrate that increasing temperatures in cold climate regions may change the seasonality of groundwater recharge, by altering the main recharge period from being snowmelt-dominated (spring) to rain-dominated (winter). Additionally, this is connected to the duration of the growing season, which impedes groundwater recharge. The coupled effect of this on groundwater in the study area has led to a significant decrease in groundwater storage.

寒-温气候过渡带地下水位波动的季节性变化
在寒冷(即寒带、亚北极、多雪)气候区,动态地下水储存量受融雪时间和融雪量的影响很大。随着全球变暖,北半球的寒冷气候将过渡到温带。随着气温上升,冬季降水的主要类型将从雪变为雨。此外,生长季节延长。这对含水层补给模式有直接影响。然而,人们对改变年度补给制度对地下水储存的影响知之甚少。本文通过评价气候季节性对年内水头波动的影响,推导了气候带变化对地下水库容的影响。该研究比较了两个不同时期(1980-1989年、2001-2010年)温冷气候过渡带(Fennoscandia)的年内水头波动。这是通过将水头上升和下降与水文气象学联系起来完成的。由于温带气候带向北迁移,这两个时期之间存在季节性的变化。这对地下水位产生了负面影响,2001-2010年地下水位明显较低,特别是在气候过渡带附近。结果表明,寒冷气候区气温升高可能改变地下水补给的季节性,使补给期由春季以融雪为主转变为冬季以降雨为主。此外,这与生长季节的持续时间有关,这阻碍了地下水的补给。这对研究区地下水的耦合作用导致地下水库存量显著减少。
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 X
Journal of Hydrology X Environmental Science-Water Science and Technology
CiteScore
7.00
自引率
2.50%
发文量
20
审稿时长
25 weeks
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