Multichannel rivers; their definition and classification
Multichannel rivers; their definition and classification
The etymology and historic usage of such terms as ‘anabranch’, ‘anastamose’ and ‘braided’ within river science are reviewed. Despite several decades of modern research to define river channel typologies inclusive of single channels and multiple channel networks, typologies remain ill-conditioned and consequently ill-defined. Conventionally employed quantitative planform characteristics of river networks possibly cannot be used alone to define channel types, yet the planform remains a central part of all modern classification schemes, supplemented by sedimentological and other qualitative channel characteristics. Planform characteristics largely have been defined using non-standardised metrics describing individual network components, such as link lengths, braiding-intensity and bifurcation angles, which data often fail to separate visually-different networks of channels. We find that existing typologies remain pragmatically utilitarian rather than fundamentally physics-based and too often fail to discriminate between two distinctive and important processes integral to new channel initiation and flow-splitting: i) in-channel bar accretion, and ii) channel avulsion and floodplain excision. It is suggested that, firstly, if channel planform is to remain central to river typologies, then more rigorous quantitative approaches to the analysis of extended integral channel networks at extended reach scales (rather than network components) are required to correctly determine whether ‘visually-different’ channel patterns can be discriminated consistently; and, secondly, if such visually-different styles do in fact differ in their governing processes of formation and maintenance. A significant question is why do so many seemingly equilibrium network geometries possess a large number of anabranches in excess of predictions from theoretical considerations? The key research frontier with respect to initiating and maintaining multichannel networks remains the understanding and discrimination of accretionary-bar flow splitting versus avulsive processes. Existing and new knowledge on flow splitting processes needs to be better integrated into channel typologies
Carling, Paul
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Jansen, John
9432fc42-5e6b-43a0-945d-62c142085a85
Meshkova, Lyubov V.
c94e77f0-f237-4015-9b17-8bb25a9303b1
Carling, Paul
8d252dd9-3c88-4803-81cc-c2ec4c6fa687
Jansen, John
9432fc42-5e6b-43a0-945d-62c142085a85
Meshkova, Lyubov V.
c94e77f0-f237-4015-9b17-8bb25a9303b1
Carling, Paul, Jansen, John and Meshkova, Lyubov V.
(2013)
Multichannel rivers; their definition and classification.
Earth Surface Processes and Landforms.
(doi:10.1002/esp.3419).
Abstract
The etymology and historic usage of such terms as ‘anabranch’, ‘anastamose’ and ‘braided’ within river science are reviewed. Despite several decades of modern research to define river channel typologies inclusive of single channels and multiple channel networks, typologies remain ill-conditioned and consequently ill-defined. Conventionally employed quantitative planform characteristics of river networks possibly cannot be used alone to define channel types, yet the planform remains a central part of all modern classification schemes, supplemented by sedimentological and other qualitative channel characteristics. Planform characteristics largely have been defined using non-standardised metrics describing individual network components, such as link lengths, braiding-intensity and bifurcation angles, which data often fail to separate visually-different networks of channels. We find that existing typologies remain pragmatically utilitarian rather than fundamentally physics-based and too often fail to discriminate between two distinctive and important processes integral to new channel initiation and flow-splitting: i) in-channel bar accretion, and ii) channel avulsion and floodplain excision. It is suggested that, firstly, if channel planform is to remain central to river typologies, then more rigorous quantitative approaches to the analysis of extended integral channel networks at extended reach scales (rather than network components) are required to correctly determine whether ‘visually-different’ channel patterns can be discriminated consistently; and, secondly, if such visually-different styles do in fact differ in their governing processes of formation and maintenance. A significant question is why do so many seemingly equilibrium network geometries possess a large number of anabranches in excess of predictions from theoretical considerations? The key research frontier with respect to initiating and maintaining multichannel networks remains the understanding and discrimination of accretionary-bar flow splitting versus avulsive processes. Existing and new knowledge on flow splitting processes needs to be better integrated into channel typologies
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e-pub ahead of print date: 2013
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Earth Surface Dynamics
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Local EPrints ID: 351037
URI: http://eprints.soton.ac.uk/id/eprint/351037
ISSN: 0197-9337
PURE UUID: f0a4c1c7-1f13-4ea6-9155-475a51d8bdf7
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Date deposited: 15 Apr 2013 08:15
Last modified: 14 Mar 2024 13:35
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Author:
John Jansen
Author:
Lyubov V. Meshkova
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