Water

25 pages, 20451 KB

Open AccessArticle

A Framework for Refined Hydrodynamic Model Based on High Resolution Urban Hydrological Unit

by Pan Wu, Tao Wang, Zhaoli Wang, Haoyu Jin and Xiaohong Chen

Water 2026, 18(1), 92; https://doi.org/10.3390/w18010092 (registering DOI) - 30 Dec 2025

With the accelerating pace of urbanization, cities are increasingly affected by rainstorm and flood disasters, which pose severe threats to the safety of residents’ lives and property. Existing models are increasingly inadequate in meeting the accuracy requirements for flood simulation in highly urbanized [...] Read more.

With the accelerating pace of urbanization, cities are increasingly affected by rainstorm and flood disasters, which pose severe threats to the safety of residents’ lives and property. Existing models are increasingly inadequate in meeting the accuracy requirements for flood simulation in highly urbanized regions. Thus, it is urgent to develop a new method for flood inundation simulation based on high-resolution urban hydrological units. The novelty of the model lies in the novel structure of the high-resolution Urban Hydrological Units model (HRGM), which replaces coarse sub-catchments with a fine-grained network of urban hydrological units. The primary innovation is the node-based coupling strategy, in which the HRGM provides precise overflow hydrographs at drainage inlets as point sources for LISFLOOD-FP, rather than relying on diffuse runoff inputs from larger areas. In this paper, a high-resolution hydraulic model (HRGM) based on urban hydrological units coupled with a 2D hydrodynamic model (LISFLOOD-FP) was constructed and successfully applied in the Chebeichong watershed. Results show that the model’s simulations align well with observed data, achieving a Nash efficiency coefficient above 0.8 under typical rainfall events. Compared with the SWMM model, the simulation results of HRGM were significantly improved and more consistent with measured results. Taking the rainstorm event on 10 August 2021 as an example, the Nash coefficient increased from 0.7 to 0.85, while the peak flow error decreased markedly from 15.8% to 3.1%. It should be emphasized that urban waterlogging distribution is not continuous but appears as patchy, discontinuous, and fragmented patterns due to the segmentation and blocking effects of roads and buildings in urban areas. The framework presented in this study shows potential for application in other regions requiring flood risk assessment at urban agglomeration scales, offering a valuable reference for advancing flood prediction methodologies and disaster mitigation strategies. Full article

(This article belongs to the Topic Basin Analysis and Modelling)

23 pages, 4147 KB

Open AccessArticle

Physicochemical Conditions Shaping Phytoplankton Development in Shallow Lakes of Bellsund During the Ablation Season, West Spitsbergen

by Marta Ziółek, Małgorzata Poniewozik, Łukasz Franczak and Magdalena Kończak

Water 2026, 18(1), 91; https://doi.org/10.3390/w18010091 (registering DOI) - 30 Dec 2025

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