Gravity Governs Shear Localization in Confined Dense Granular Flows

Prediction of flow profiles of slowly sheared granular materials is a major geophysical and industrial challenge. Understanding the role of gravity is particularly important for future planetary exploration in varying gravitational environments. Using the principle of minimization of energy dissipat...

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Veröffentlicht in:	arXiv.org 2021-05
Hauptverfasser:	Shaebani, M Reza, Török, János, Maleki, Maniya, Madani, Mahnoush, Harrington, Matt, Rice, Allyson, Losert, Wolfgang
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Sprache:	eng
Schlagworte:	Acceleration Angular velocity Confining Energy dissipation Extraterrestrial environments Extraterrestrial matter Granular materials Localization Physics - Soft Condensed Matter Physics - Statistical Mechanics Scaling laws Shear flow Shear localization Shear strain Shear zone Space exploration Strain localization Thickness
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description	Prediction of flow profiles of slowly sheared granular materials is a major geophysical and industrial challenge. Understanding the role of gravity is particularly important for future planetary exploration in varying gravitational environments. Using the principle of minimization of energy dissipation, and combining experiments and variational analysis, we disentangle the contributions of the gravitational acceleration and confining pressure on shear strain localization induced by moving fault boundaries at the bottom of a granular layer. The flow profile is independent of the gravity for geometries with a free top surface. However, under a confining pressure or if the sheared layer withstands the weight of the upper layers, increasing gravity promotes the transition from closed shear zones buried in the bulk to open ones that intersect the top surface. We show that the center position and width of the shear zone and the axial angular velocity at the top surface follow universal scaling laws when properly scaled by the gravity, applied pressure, and layer thickness. Our finding that the flow profiles lie on a universal master curve opens the possibility to predict the quasistatic shear flow of granular materials in extraterrestrial environments.
doi_str_mv	10.48550/arxiv.2105.07257
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subjects	Acceleration Angular velocity Confining Energy dissipation Extraterrestrial environments Extraterrestrial matter Granular materials Localization Physics - Soft Condensed Matter Physics - Statistical Mechanics Scaling laws Shear flow Shear localization Shear strain Shear zone Space exploration Strain localization Thickness
title	Gravity Governs Shear Localization in Confined Dense Granular Flows
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