https://doi.org/10.1140/epjb/e2005-00050-6
Ripple formation over a sand bed submitted to a laminar shear flow
Groupe Matière Condensée et Matériaux, UMR 6626,
Université Rennes 1, 35042 Rennes Cedex, France
Corresponding author: a alexandre.valance@univ-rennes1.fr
Received:
2
September
2004
Revised:
3
December
2004
Published online:
25
February
2005
We investigate the process of ripple formation in a viscous fluid when a
sand bed is submitted to a laminar shear flow. We propose a new
description for the sand transport which takes
into account the fact that the transport rate does not adapt instantaneously
to a change of the fluid velocity due to grain inertia. It introduces
a new length, called here after equilibrium length leq,
corresponding to the distance needed for a immobile grain to equilibrate its velocity with
that of the fluid. The transport rate is therefore found to depend not only
on the fluid shear stress and bed slope (as usually assumed) but also
on grain inertia. Within the framework of this model
we analyzed the mechanisms of the sand bed instability.
It is found that the instability
results from the competition between the destabilizing effect of fluid inertia
and the stabilizing ones of grain inertia and bed slope.
We derive analytical scaling laws for the most amplified wavelength,
its growth rate and phase velocity. We found in particular that
at small particle Reynolds number Rep, the most amplified
wavelength scales as the viscous length 
defined as
(where γ is the shear rate and ν the fluid
viscosity) and at large Rep it scales
as the equilibrium length leq.
Our results are compared with available experimental data.
PACS: 45.70.-n – Granular systems / 47.15.-x – Laminar flows / 47.54.+r – Pattern selection; pattern formation
© EDP Sciences, Società Italiana di Fisica, Springer-Verlag, 2005
