We propose an approach to reduce a comprehensive set of 186 mesoscale catchments in Switzerland to fewer response types to climate change and to name sensitive regions as well as catchment characteristics that govern hydrological change. We classified the hydrological responses of our study catchments through an agglomerative-hierarchical cluster analysis, and we related the dominant explanatory variables, i.e. the determining catchment properties and climate change signals, to the catchments' hydrological responses by means of redundancy analysis. All clusters except for one exhibit clearly decreasing summer runoff and increasing winter runoff. This seasonal shift was observed for the near future period (2025–2046) but is particularly obvious in the far future period (2074–2095). Within a certain elevation range (between 1000 and 2500 m a.s.l.), the hydrological change is basically a function of elevation, because the latter governs the dominant hydro-climatological processes associated with temperature, e.g. the ratio of liquid to solid precipitation and snow melt processes. For catchments below the stated range, hydrological change is mainly a function of precipitation change, which is not as pronounced as the temperature signal is. Future impact studies in Switzerland can be conducted on a reduced sample of catchments representing the sensitive regions or covering a range of altitudes.
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机译:我们提出了一种方法,以减少瑞士的186个中尺度集水区的集合,减少对气候变化的响应类型,并命名敏感区域以及控制水文变化的集水区特征。我们通过集聚-层次聚类分析对研究流域的水文响应进行分类,并通过冗余分析将主要的解释变量(即确定流域性质和气候变化信号)与流域的水文响应相关联。除一个集群外,所有集群均表现出明显的夏季径流减少和冬季径流增加。在不久的将来时期(2025年至2046年)观察到这种季节性变化,但在遥远的将来时期(2074年至2095年)尤为明显。在一定的海拔范围内(1000至2500 m a.s.l.),水文变化基本上是海拔的函数,因为后者决定了与温度相关的主要水文气候过程,例如温度。液体与固体沉淀和融雪过程的比率。对于低于规定范围的流域,水文变化主要是降水变化的函数,其不如温度信号明显。瑞士未来的影响研究可以在代表敏感地区或覆盖一定高度范围的流域减少样本上进行。
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