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Main Authors: Ulloa, Hugo N., Trewhela, Tomás
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2604.24702
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author Ulloa, Hugo N.
Trewhela, Tomás
author_facet Ulloa, Hugo N.
Trewhela, Tomás
contents As granular materials flow and settle, interactions among particles of different sizes or properties drive mixing and segregation, producing rich dynamics that reshape systems ranging from industrial hoppers to planetary surfaces. A hallmark of such polydisperse flows is shear-driven size segregation, whereby particles rearrange so that larger grains migrate above smaller ones. Despite substantial progress in modelling granular flow and segregation, key questions concerning the underlying mechanisms remain unresolved. In particular, the physics of granular mixing -- the natural counterpart of segregation -- has received far less attention. Here, we investigate the dynamics of initially segregated granular materials driven out of equilibrium by external shear. We ask: what controls the extent and rate of segregation and mixing in a sheared granular flow? Answering this question is essential for understanding how external forcing disrupts stable and unstable particle configurations and for optimising processes that require controlled mixing. Using theoretical analysis and numerical experiments, we develop and validate a scaling framework that quantifies the mixing dynamics. Our results provide new insight into the physics of granular flows and lay the foundation for improved prediction and design in both natural and industrial settings.
format Preprint
id arxiv_https___arxiv_org_abs_2604_24702
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Shear-driven mixing of segregated granular materials
Ulloa, Hugo N.
Trewhela, Tomás
Soft Condensed Matter
As granular materials flow and settle, interactions among particles of different sizes or properties drive mixing and segregation, producing rich dynamics that reshape systems ranging from industrial hoppers to planetary surfaces. A hallmark of such polydisperse flows is shear-driven size segregation, whereby particles rearrange so that larger grains migrate above smaller ones. Despite substantial progress in modelling granular flow and segregation, key questions concerning the underlying mechanisms remain unresolved. In particular, the physics of granular mixing -- the natural counterpart of segregation -- has received far less attention. Here, we investigate the dynamics of initially segregated granular materials driven out of equilibrium by external shear. We ask: what controls the extent and rate of segregation and mixing in a sheared granular flow? Answering this question is essential for understanding how external forcing disrupts stable and unstable particle configurations and for optimising processes that require controlled mixing. Using theoretical analysis and numerical experiments, we develop and validate a scaling framework that quantifies the mixing dynamics. Our results provide new insight into the physics of granular flows and lay the foundation for improved prediction and design in both natural and industrial settings.
title Shear-driven mixing of segregated granular materials
topic Soft Condensed Matter
url https://arxiv.org/abs/2604.24702