Targeting lateral connectivity and morphodynamics in a large river‐floodplain system: The upper Rhine River |
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| Authors: | M Díaz‐Redondo G Egger M Marchamalo C Damm RP de Oliveira L Schmitt |
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| Affiliation: | 1. School of Civil Engineering, University of Lisbon, Lisbon, Portugal;2. Department of Wetland Ecology, Karlsruhe Institute of Technology, Karlsruhe, Germany;3. Department of Land Morphology and Engineering, Universidad Politécnica de Madrid, Madrid, Spain;4. UMR LIVE 7362 CNRS‐ENGEES, University of Strasbourg, Strasbourg, France |
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| Abstract: | As a consequence of historical damming and channelization, most large rivers are disconnected from their floodplains, which therefore endure severe deficits in fluvial dynamics. Regaining some degree of lateral connectivity can lead to improved geomorphological and biological interactions. Yet, it is necessary to take into account limitations posed by current uses and legislation. This study presents a methodological approach to the selection of a realistic restoration target for a heavily modified large river segment, the free‐flowing Upper Rhine River downstream of Iffezheim dam (France–Germany border), based on the analysis of the existing biogeomorphic deficits, constraints set by human uses, and previous restoration experiences. To achieve the selected restoration target, proposed scenarios include embankment removal, bank lowerings, and side channel widenings with the aim of increasing lateral hydrological connectivity and promoting morphodynamics (bank erosion in lateral channels) that allow for the renewal of floodplain habitats. Results from 2‐D hydraulic simulations allow for a sensitivity analysis, comparing the current situation with the proposed scenarios, through parameters such as shore length of side channels actively connected at both ends to the main channel (eupotamon), and shear stress as a proxy for initiation of gravel erosion. Outcomes indicate that the two proposed restoration scenarios would succeed in reconnecting side channels and in increasing areas prone to substrate erosion, while maintaining flood protection and the heaviest navigation use among European rivers. The presented approach aids in the assessment of potential large river restoration scenarios and, thus, in the discussion of water management strategies. |
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| Keywords: | boundary conditions hydrodynamic modelling lateral connectivity morphodynamics restoration scenarios restoration target Upper Rhine River |
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