Abstract
Accurate and reliable estimates of water levels are essential to assess flood risk in river systems. In current practice, uncertainties involved and the sensitivity of water levels to these uncertainties are studied in single-branch rivers, while many rivers in deltas consist of multiple distributaries. In a bifurcating river, a feedback mechanism exists between the downstream water levels and the discharge distribution at the bifurcation. This paper aims to quantify the sensitivity of water levels to main channel roughness in a bifurcating river system. Water levels are modelled for various roughness scenarios under a wide range of discharge conditions using a one-dimensional hydraulic model. The results show that the feedback mechanism reduces the sensitivity of water levels to local changes of roughness in comparison to the single-branch river. However, in the smaller branches of the system, water-level variations induced by the changes in discharge distribution can exceed the water-level variations of the single-branch river. Therefore, water levels throughout the entire system are dominated by the conditions in the largest branch. As the feedback mechanism is important, the river system should be considered as one interconnected system in river maintenance of rivers, flood-risk analyses, and future planning of river engineering works.
Highlights
Around the world, river flooding is one of the largest natural hazards, causing large economic damage and loss of life [1]
The aim of this study is to quantify the sensitivity of water levels in a bifurcating river system to variations in main channel roughness to support flood-risk management
In this paper the sensitivity of water levels to main channel roughness is quantified for the bifurcating Dutch river Rhine system
Summary
River flooding is one of the largest natural hazards, causing large economic damage and loss of life [1]. Risks of flooding are especially high in river deltas. Under the influence of a changing climate, higher river discharges are expected to occur, thereby increasing flood risk. Deltaic rivers split into multiple branches, with every branch carrying a certain fraction of the upstream discharge. The distribution of this upstream over the branches has a major influence on the flood risks over the downstream branches [2]. Assessing the sensitivities of water levels for bifurcating rivers is essential for accurate flood-risk management
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