IMPACT OF CLIMATE CHANGE ON HYDROLOGICAL AND METEOROLOGICAL QUANTITIES IN WATERSHED SCALE

SGEM International Multidisciplinary Scientific GeoConference� EXPO Proceedings Pub Date : 2022-12-27 DOI:10.5593/sgem2022v/3.2/s12.11

M. Bednar, D. Marton

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Abstract

Climate change�s effect on nature, the human population and water resources have become a serious issue. It affects the delicate balance between precipitation, evaporation, discharge and other interactions between the atmosphere and surface, which is represented by the water cycle as we know it. The adaptation of water resources to changing hydrological conditions within basins is crucial. However, the uncertainty of climate change makes it difficult for hydrological models to evaluate future conditions. To suppress the uncertainty that stems from the hydrological model itself, we propose a new modified lumped water balance model in monthly time steps to simulate the rainfallrunoff process more precisely, which will help to evaluate the predicted hydrological and climatological conditions under the uncertainty of climate change. Assessment of the effects of climate change is presented on the catchment above the Vir I reservoir on the Svratka River in the Czech Republic in Central Europe. The uncertainty of climate change is represented by an ensemble of future climatological projections using representative concentration pathways (RCP) scenarios. Two ensembles were generated: the first using RCP 4.5 and the second using RCP 8.5. Both scenarios were coupled with 18 global climate models which are available in LARS-WG 6 software. Analysis of the generated climatological quantities for both ensembles in the 2030s, 2050s, and 2090s periods on annual average relative to baseline values showed an increase in mean temperature of 21.4% (1.4�C), 33.1% (2.2�C) and 55.5% (3.7�C), an increase of potential evapotranspiration of 7.2%, 11.4% and 20.5%, and an increase in precipitation of 4.8%, 5.3% and 5.5%, respectively. Evaluated long-term mean streamflow showed a decrease in the 2030s, 2050s and 2090 of 1.0%, 3.1% and 2.9%, respectively, for RCP 4.5 and an increase of 1.8% in the 2030s but then also a decrease in the 2050s and 2090s of 2.3% and 17.9%, respectively, for RCP 8.5.

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气候变化对流域水文气象量的影响

气候变化对自然、人口和水资源的影响已成为一个严重的问题。它影响着降水、蒸发、排放和大气与地表之间的其他相互作用之间的微妙平衡，这就是我们所知道的水循环。使水资源适应流域内不断变化的水文条件至关重要。然而，气候变化的不确定性使得水文模型难以评估未来的条件。为了抑制水文模型本身的不确定性，我们提出了一个新的修正的月时间步长的集总水平衡模型，以更精确地模拟降雨径流过程，这将有助于评估在气候变化不确定性下预测的水文和气候条件。本文评估了气候变化对中欧捷克共和国Svratka河上Vir I水库以上集水区的影响。气候变化的不确定性由使用代表性浓度路径(RCP)情景的未来气候预估集合来表示。生成了两个集合:第一个使用RCP 4.5，第二个使用RCP 8.5。这两种情景与LARS-WG 6软件中提供的18种全球气候模式相结合。对2030年代、2050年代和2090年代两个组合产生的气候学量的分析显示，相对于基线年平均值，平均温度增加了21.4%(1.4°C)、33.1%(2.2°C)和55.5%(3.7°C)，潜在蒸散增加了7.2%、11.4%和20.5%，降水增加了4.8%、5.3%和5.5%。评估的长期平均流量在2030年代、2050年代和2090年分别减少1.0%、3.1%和2.9% (RCP 4.5)，在2030年代增加1.8% (RCP 8.5)，然后在2050年代和2090年代分别减少2.3%和17.9% (RCP 8.5)。

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SGEM International Multidisciplinary Scientific GeoConference� EXPO Proceedings

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