Analysis of antidune migration direction

Antidunes are bed forms characteristic of upper regime unidirectional flows. Contrary to bed forms developed in lower regime flows, antidunes not only can propagate in the downstream direction but can propagate upstream or remain stationary. In this work we analyze the stable hydraulic conditions th...

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Bibliographic Details
Published in:Journal of Geophysical Research: Earth Surface 2011-06, Vol.116 (F2), p.n/a
Main Authors: Núñez-González, Francisco, Martín-Vide, Juan P.
Format: Article
Language:English
Subjects:
antidunes
bed forms
Downstream
Energy balance
Froude number
Geomorphology
Hydraulics
Hydrology
Pressure head
River beds
sediment transport
Sedimentary structures
Sedimentation & deposition
Stream flow
Upstream
Water depth
Wave height
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Summary:Antidunes are bed forms characteristic of upper regime unidirectional flows. Contrary to bed forms developed in lower regime flows, antidunes not only can propagate in the downstream direction but can propagate upstream or remain stationary. In this work we analyze the stable hydraulic conditions that determine each of the three antidune movement possibilities, and a new theory is developed for distinguishing the occurrence of each of these conditions. The theory is developed from an energy balance over a symmetrical antidune; for this, the Bernoulli equation is applied between the antidune crest and antidune trough, and the pressure head is corrected to account for the centrifugal forces generated by curvilinear flow. Manipulation of the fundamental equations produces an antidune mobility dimensionless number (Fa), dependent on the Froude number, the mean water depth, and the antidune wavelength. The critical value of the antidune mobility number (Fa = 1) corresponds to the stationary condition, while values higher and lower than the critical correspond to downstream and upstream propagation, respectively. Theory predicts that for a given Froude number, downstream‐migrating antidunes are formed for higher water depth–wavelength ratios than for upstream‐migrating antidunes. Likewise, by introducing a restriction for the maximum stationary wave height above antidunes, theory predicts that downstream‐migrating antidunes could attain steeper height–wavelength ratios than upstream‐migrating antidunes. Comparison with published experimental data in literature largely showed agreement between theory and experimental observations. Key Points A new theory is presented for explaining the direction of movement of antidunes Theory is based on a simplified analysis of flow hydraulics over antidunes Downstream‐migrating antidunes could be steeper than upstream‐migrating
ISSN:0148-0227
2169-9003
2156-2202
2169-9011
DOI:10.1029/2010JF001761