Historical memory in remotely sensed soil moisture can enhance flash flood modeling for headwater catchments in Germany

IF 5.9 1区 地球科学 Q1 ENGINEERING, CIVIL Journal of Hydrology Pub Date : 2024-11-23 DOI:10.1016/j.jhydrol.2024.132395
Yan Liu , Yong Chang , Ingo Haag , Julia Krumm , Visakh Sivaprasad , Dirk Aigner , Harry Vereecken , Harrie-Jan Hendricks Franssen
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Abstract

The wetness precondition of a catchment affects available soil water storage capacity and infiltration rate, thus influences flash flood generation. Remotely sensed (RS) soil moisture (SM) can provide valuable information on catchment wetness, but typically only represents the top 5 cm of the land surface. However, hydrological models for flash flood simulation need to consider deeper layers to calculate the total soil water storage. Therefore, a key challenge is to link RS SM to total soil water storage and assimilate RS SM into flash flood models to correctly describe initial catchment wetness. In this study, we developed an approach to combine present and antecedent RS SM to infer present soil water storage based on four regression models. The inferred soil water storage from SMAP (soil moisture active passive) SM was assimilated into the operational LARSIM (Large Area Runoff Simulation Model) hydrological model. We tested this new approach with 12 events in the headwater catchments Körsch, Adenauer Bach and Fischbach in Germany. Results show that random forest regression performs the best among the four regression models. The BIC (Bayesian Information Criterion) score suggests that regressions considering antecedent RS SM can well infer soil water storage, resulting in R2 of 0.85, 0.94 and 0.93 for the Körsch, Adenauer Bach and Fischbach catchments, respectively. Compared to the open loop (without data assimilation) simulations, our approach enhanced the general performance of event simulations with average KGE increases of 0.09, 0.24 and 0.33 for the Körsch, Adenauer Bach and Fischbach, respectively; and the mean error in the 12 simulated event peaks is reduced 15 %. Moreover, the simulation uncertainty is reduced, too. The transferability of the proposed approach to other RS products is also discussed. Although assimilating RS SM can enhance flash flood modeling, it is primarily affected by the uncertainty in precipitation. In the future, the proposed approach should be tested with more catchments and events to verify its general validity.
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遥感土壤水分的历史记忆可增强德国山洪暴发的源头流域建模能力
集水区的湿润前提条件会影响土壤的蓄水能力和渗透率,从而影响山洪的生成。遥感(RS)土壤湿度(SM)可提供有关集水区湿润度的宝贵信息,但通常只代表地表顶部 5 厘米。然而,用于山洪模拟的水文模型需要考虑更深的层,以计算土壤的总蓄水量。因此,如何将 RS SM 与土壤总蓄水量联系起来,并将 RS SM 同化到山洪模型中,以正确描述初始流域湿润度,是一项关键挑战。在本研究中,我们基于四个回归模型,开发了一种结合当前和前兆 RS SM 来推断当前土壤蓄水量的方法。从 SMAP(土壤水分主动被动)SM 中推断出的土壤蓄水量被同化到运行中的 LARSIM(大面积径流模拟模型)水文模型中。我们用德国 Körsch、Adenauer Bach 和 Fischbach 等上游集水区的 12 个事件对这一新方法进行了测试。结果表明,随机森林回归在四种回归模型中表现最佳。BIC(贝叶斯信息标准)得分表明,考虑了前因 RS SM 的回归能够很好地推断土壤蓄水量,在 Körsch、Adenauer Bach 和 Fischbach 流域的 R2 分别为 0.85、0.94 和 0.93。与开环(无数据同化)模拟相比,我们的方法提高了事件模拟的总体性能,Körsch、Adenauer Bach 和 Fischbach 流域的 KGE 平均值分别增加了 0.09、0.24 和 0.33;12 个模拟事件峰值的平均误差减少了 15%。此外,模拟的不确定性也有所降低。此外,还讨论了所建议方法对其他 RS 产品的可移植性。虽然吸收 RS SM 可以增强山洪模型,但它主要受到降水不确定性的影响。今后,应使用更多的流域和事件对所提出的方法进行测试,以验证其普遍有效性。
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来源期刊
Journal of Hydrology
Journal of Hydrology 地学-地球科学综合
CiteScore
11.00
自引率
12.50%
发文量
1309
审稿时长
7.5 months
期刊介绍: The Journal of Hydrology publishes original research papers and comprehensive reviews in all the subfields of the hydrological sciences including water based management and policy issues that impact on economics and society. These comprise, but are not limited to the physical, chemical, biogeochemical, stochastic and systems aspects of surface and groundwater hydrology, hydrometeorology and hydrogeology. Relevant topics incorporating the insights and methodologies of disciplines such as climatology, water resource systems, hydraulics, agrohydrology, geomorphology, soil science, instrumentation and remote sensing, civil and environmental engineering are included. Social science perspectives on hydrological problems such as resource and ecological economics, environmental sociology, psychology and behavioural science, management and policy analysis are also invited. Multi-and interdisciplinary analyses of hydrological problems are within scope. The science published in the Journal of Hydrology is relevant to catchment scales rather than exclusively to a local scale or site.
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