Scale-free channeling patterns near the onset of erosion of sheared granular beds

Erosion shapes our landscape and occurs when a sufficient shear stress is exerted by a fluid on a sedimented layer. What controls erosion at a microscopic level remains debated, especially near the threshold forcing where it stops. Here we study experimentally the collective dynamics of the moving p...

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Bibliographic Details
Published in:arXiv.org 2016-06
Main Authors: Aussillous, Pascale, Zou, Zhenhai, Guazzelli, Élisabeth, Le, Yan, Wyart, Matthieu
Format: Article
Language:English
Subjects:
Channeling
Channels
Erosion control
Flux
Laminar flow
Particle interactions
Phase transitions
Shear stress
Online Access:Get full text
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Summary:Erosion shapes our landscape and occurs when a sufficient shear stress is exerted by a fluid on a sedimented layer. What controls erosion at a microscopic level remains debated, especially near the threshold forcing where it stops. Here we study experimentally the collective dynamics of the moving particles, using a set-up where the system spontaneously evolves toward the erosion onset. We find that the spatial organization of the erosion flux is heterogeneous in space, and occurs along channels of local flux \(\sigma\) whose distribution displays scaling near threshold and follows \(P(\sigma)\sim J/\sigma\), where \(J\) is the mean erosion flux. Channels are strongly correlated in the direction of forcing but not in the transverse direction. We show that these results quantitatively agree with a model where the dynamics is governed by the competition of disorder (which channels mobile particles) and particle interactions (which reduces channeling). These observations support that for laminar flows, erosion is a dynamical phase transition which shares similarity with the plastic depinning transition occurring in dirty superconductors. The methodology we introduce here could be applied to probe these systems as well.
ISSN:2331-8422
DOI:10.48550/arxiv.1606.01300