Accounting for density-driven secondary flows at river confluences with a 2-D depth-averaged hydro-morphodynamic model

IF 4.6 2区环境科学与生态学 Q1 COMPUTER SCIENCE, INTERDISCIPLINARY APPLICATIONS

Environmental Modelling & Software Pub Date : 2025-10-09 DOI:10.1016/j.envsoft.2025.106735

T. Lazzarin, L. Xu, S. Yuan, A.J.F. Hoitink, D.P. Viero

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引用次数: 0

Abstract

At river confluences, transverse density gradients induce secondary currents that interact with those generated by streamline curvature, affecting flow patterns and sediment dynamics. Here, a hydro- and morphodynamic two-dimensional numerical model is enhanced to account for density-driven secondary flows. The model solves the Shallow Water Equations coupled with transport equations for water temperature and streamwise angular momentum, driven by both streamline curvature and spanwise density gradients. A morphodynamic module computes bedload, suspended sediment transport, and the bed evolution. The model is tested against three-dimensional CFD results and applied to the Yangtze River and Poyang Lake confluence in both fixed and mobile bed modes. The results, which favorably compare to measured data, highlight the role of temperature dynamics in the pattern and intensity of secondary currents and their contribution in shaping the riverbed. The model allows for long-term morphodynamic simulations at low computational effort.

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用二维深度平均水形态动力学模型计算河流汇合处密度驱动的二次流

在河流汇合处，横向密度梯度诱导的二次流与流线曲率产生的二次流相互作用，影响水流形态和泥沙动力学。在这里，水力和形态动力学的二维数值模型得到加强，以说明密度驱动的二次流。该模型求解了由流线曲率和展向密度梯度驱动的浅水方程、水温输运方程和流向角动量输运方程。形态动力学模块计算了河床负荷、悬浮泥沙输运和河床演化。利用三维CFD结果对模型进行了验证，并应用于长江与鄱阳湖汇合处固定河床和移动河床两种模式。研究结果与实测数据相比较，突出了温度动态在二次流模式和强度中的作用，以及它们对河床形成的贡献。该模型允许低计算量的长期形态动力学模拟。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Environmental Modelling & Software 工程技术-工程：环境

CiteScore

9.30

自引率

8.20%

发文量

241

审稿时长

60 days

期刊介绍： Environmental Modelling & Software publishes contributions, in the form of research articles, reviews and short communications, on recent advances in environmental modelling and/or software. The aim is to improve our capacity to represent, understand, predict or manage the behaviour of environmental systems at all practical scales, and to communicate those improvements to a wide scientific and professional audience.