Wave train model for knickpoint migration

Rivers respond to a drop in their base level by incising the topography. The upstream propagation of an incision, as usually depicted by a knickpoint migration, is thought to depend on several parameters such as the drainage area, lithology, and the amplitude of the base level drop. We first investi...

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Bibliographic Details
Published in:Geomorphology (Amsterdam, Netherlands) Netherlands), 2009-05, Vol.106 (3), p.376-382
Main Authors: Loget, Nicolas, Van Den Driessche, Jean
Format: Article
Language:English
Subjects:
Base-level drop
Earth Sciences
Earth, ocean, space
Exact sciences and technology
Geomorphology
Knickpoint
Marine
Marine and continental quaternary
Messinian Salinity Crisis
Migration rate
Sciences of the Universe
Stratigraphy
Surficial geology
Wave train
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Summary:Rivers respond to a drop in their base level by incising the topography. The upstream propagation of an incision, as usually depicted by a knickpoint migration, is thought to depend on several parameters such as the drainage area, lithology, and the amplitude of the base level drop. We first investigate the case of the Messinian Salinity Crisis that was characterized by the extreme base level fall (1500 m) of the Mediterranean Sea at the end of the Miocene. The response of drainage areas of three orders of magnitude (10 3 to 10 6 km 2) highlights the dominant role of the drainage area (with a square root relationship) in controlling the knickpoint migration after a base level fall. A compilation of mean rates of knickpoint propagation for time durations ranging from 10 2 to 10 7 years displays a similar relationship indicating that successive wave trains of knickpoint can migrate in a river: first, wave trains linked to the release of the alluvial cover and then, wave trains related to the bedrock incision, which correspond to the real time response of rivers. Wave trains with very low retreat rates (long lived knickpoints > 1 My) rather correspond to the response time of regional landscape.
ISSN:0169-555X
1872-695X
DOI:10.1016/j.geomorph.2008.10.017