Base flow reduction due to surface water and groundwater evapotranspiration from wetlands of Liběchovka catchment: comparison of measurements and calculation by Oudin’s method

Q4 Earth and Planetary Sciences

Geoscience Research Reports Pub Date : 2023-05-09 DOI:10.3140/zpravy.geol.2023.01

Karel Pátek, Jiří Bruthans

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Abstract

This study is focused on the base flow decrease due to surface water and groundwater evapotranspiration (ET) in wetlands of the Liběchovka catchment. Evapotranspiration in wetlands can significantly affect stream discharge, and its influence will probably still increase in the future due to the global rise of temperatures caused by climate change. The study site is located in the upper part of Liběchovka catchment (Fig. 1). This wetland hosts a small stream supplied by rather steady groundwater inflow, representing the favourable site for detection of the effect of ET. V notch weir and two piezometers were used to monitor stream discharge and wetland water table in 30 minute periods (Fig. 2). Diurnal periodical oscillations of water flow and water table caused by ET were observed (Fig. 3). They occurred in the summer part of the year, especially on sunny days without rain. The amplitude of water table level oscillation was increasing with increasing temperature (Fig. 4). Calculation showed that evapotranspiration reduced the water flow, on average, by 15 % on the warm sunny days. The maximum daily reduction was up to 32 %. Direct measurements were compared with the potential ET calculated using the Oudin’s method (Oudin 2005). The ET from the measurement was 45 % of the potential ET calculated by Oudin’s method. In the next step, the Oudin’s method was used to calculate the potential ET of all wetlands in Liběchovka catchment upstream from the Želízy village, where gauging station of ČHMÚ is situated. The original discharge not reduced by the wetland ET was defined as the sum of the wetland potential ET and the mean annual measured discharge. Due to the ET from wetlands (years 2015–2020), the discharge was reduced on average by 13 %. If only the summer months of July and August were considered, it was reduced, on average, by 26 % and by 39 % in the driest day recorded in this period. To estimate the role of groundwater abstraction on the Liběchovka stream during the period of 2015–2020, the sum of measured stream discharge, groundwater abstraction and wetland ET was calculated. From this sum, 71.5 % represented the directly measured water flow, 18.2 % was the groundwater abstraction, and 10.3 % was the wetland ET (Fig. 8).

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liberchovka集水区湿地地表水和地下水蒸散引起的基流减少:测量值与Oudin方法计算的比较

本文主要研究了利波廖夫卡流域湿地地表水和地下水蒸散发(ET)对基流的影响。湿地的蒸散发作用可以显著影响河流流量，并且由于气候变化导致的全球气温上升，其影响在未来可能还会增加。研究站点位于上部的自由ěchovka流域(图1)。这个湿地主机提供的一条小溪,而稳定的地下水流入,代表有利的网站检测ET的影响。V缺口堰和两个压强计被用来监测流流量和湿地水位在30分钟的时间(图2)。昼夜周期性振荡引起的水量和水位等观察(图3)。他们发生在今年夏天的一部分,尤其是在没有下雨的晴天。水位振荡幅度随温度升高而增大(图4)。计算表明，在温暖晴天，蒸散发使水流量平均减少15%。每日最大减量可达32%。将直接测量值与使用Oudin方法计算的潜在蒸散发进行了比较(Oudin 2005)。测量所得的ET是Oudin方法计算的潜在ET的45%。下一步，利用Oudin方法计算ČHMÚ测量站所在的Želízy村上游的lib chovka集水区所有湿地的潜在ET。未被湿地ET减少的原始流量定义为湿地潜在ET与年平均实测流量之和。由于湿地的ET(2015-2020年)，排放量平均减少了13%。如果只考虑夏季的7月和8月，在这一时期有记录的最干旱的一天，降雨量平均减少了26%，减少了39%。为了估算2015-2020年地下水抽采对利波涅乔夫卡河的影响，计算了实测河流流量、地下水抽采量和湿地ET的总和。其中71.5%为直接测量的水流量，18.2%为地下水抽采量，10.3%为湿地ET(图8)。

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

Geoscience Research Reports Earth and Planetary Sciences-Stratigraphy

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0.30

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0.00%

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期刊介绍： Geoscience Research Reports inform the general public about current state of knowledge in a wide variety of geologic subjects. Here the reader will find the results of research conducted by the academia, by the public as well as private sectors. The articles are distributed into individual science topics – regional geology, stratigraphy, Quaternary research, engineering geology, paleontology, mineralogy, petrology, geochemistry, hydrogeology, mineral resources, geophysics, geological information system and international activities.