4.6 Article

Using high-resolution regional climate models to estimate return levels of daily extreme precipitation over Bavaria

Journal

NATURAL HAZARDS AND EARTH SYSTEM SCIENCES
Volume 21, Issue 11, Pages 3573-3598

Publisher

COPERNICUS GESELLSCHAFT MBH
DOI: 10.5194/nhess-21-3573-2021

Keywords

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Funding

  1. Bayerisches Landesamt fur Umwelt [81-0270-82467/2019]

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The study uses high-resolution regional climate models to generate 10- and 100-year daily rainfall return levels, showing their suitability for producing spatially homogeneous rainfall return level products. By comparing with observational data, the higher-resolution climate models demonstrate better performance.
Extreme daily rainfall is an important trigger for floods in Bavaria. The dimensioning of water management structures as well as building codes is based on observational rainfall return levels. In this study, three high -resolution regional climate models (RCMs) are employed to produce 10- and 100 -year daily rainfall return levels and their performance is evaluated by comparison to observational return levels. The study area is governed by different types of precipitation (stratiform, orographic, convectional) and a complex terrain, with convective precipitation also contributing to daily rainfall levels. The Canadian Regional Climate Model version 5 (CRCM5) at a 12 km spatial resolution and the Weather and Forecasting Research (WRF) model at a 5 km resolution both driven by ERA -Interim reanalysis data use parametrization schemes to simulate convection. WRF at a 1.5 km resolution driven by ERAS reanalysis data explicitly resolves convectional processes. Applying the generalized extreme value (GEV) distribution, the CRCM5 setup can reproduce the observational 10 -year return levels with an areal average bias of +6.6 % and a spatial Spearman rank correlation of p = 0.72. The higher-resolution 5 km WRF setup is found to improve the performance in terms of bias (+4.7 %) and spatial correlation (p = 0.82). However, the finer topographic details of the WRF-ERAS return levels cannot be evaluated with the observation data because their spatial resolution is too low. Hence, this comparison shows no further improvement in the spatial correlation (p = 0.82) but a small improvement in the bias (2.7 %) compared to the 5 km resolution setup. Uncertainties due to extreme value theory are explored by employing three further approaches. Applied to the WRFERAS data, the GEV distributions with a fixed shape param- eter (bias is +2.5 %; p = 0.79) and the generalized Pareto (GP) distributions (bias is +2.9 %; p = 0.81) show almost equivalent results for the 10 -year return period, whereas the metastatistical extreme value (MEV) distribution leads to a slight underestimation (bias is 7.8 %; p = 0.84). For the 100 -year return level, however, the MEV distribution (bias is +2.7 %; p = 0.73) outperforms the GEV distribution (bias is +13.3 %; p = 0.66), the GEV distribution with fixed shape parameter (bias is +12.9 %; p = 0.70), and the GP distribution (bias is +11.9 %; p = 0.63). Hence, for applications where the return period is extrapolated, the MEV framework is recommended. From these results, it follows that high-resolution regional climate models are suitable for generating spatially homogeneous rainfall return level products. In regions with a sparse rain gauge density or low spatial representativeness of the stations due to complex topography, RCMs can support the observational data. Further, RCMs driven by global climate models with emission scenarios can project climate -changeinduced alterations in rainfall return levels at regional to local scales. This can allow adjustment of structural design and, therefore, adaption to future precipitation conditions.

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