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Autori principali: Pawłowski, Jarosław, Dudziak, Marcin, Baggioli, Matteo, Zhang, Jie, Surówka, Piotr
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2504.08516
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author Pawłowski, Jarosław
Dudziak, Marcin
Baggioli, Matteo
Zhang, Jie
Surówka, Piotr
author_facet Pawłowski, Jarosław
Dudziak, Marcin
Baggioli, Matteo
Zhang, Jie
Surówka, Piotr
contents Micropolar fluid theory, an extension of classical Newtonian fluid dynamics, incorporates angular velocities and rotational inertias and has long been a foundational framework for describing granular flows. We propose a macroscopic model of granular matter based on micropolar fluid dynamics, which incorporates internal rotations, couple stresses, and broken parity through odd viscosity. Our framework extends traditional micropolar theory to describe chiral granular flows driven far from equilibrium, where energy is continuously injected and dissipated. In particular, we focus on steady states and explicitly neglect energy conservation, reflecting the dissipative nature of granular systems maintained in non-equilibrium by external forcing. Within this setup, we study the lift force experienced by a test bead embedded in a compressible, parity-breaking granular flow. We analyze how odd viscosity and microrotation modify the transverse forces, using both analytical results in the linearized Stokes regime and nonlinear finite element simulations. Our results demonstrate that micropolar fluids provide a physically consistent and symmetry-informed continuum description of chiral granular matter, capable of capturing lift forces that emerge uniquely from odd transport effects.
format Preprint
id arxiv_https___arxiv_org_abs_2504_08516
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Lift force in chiral, compressible granular matter
Pawłowski, Jarosław
Dudziak, Marcin
Baggioli, Matteo
Zhang, Jie
Surówka, Piotr
Soft Condensed Matter
Fluid Dynamics
Micropolar fluid theory, an extension of classical Newtonian fluid dynamics, incorporates angular velocities and rotational inertias and has long been a foundational framework for describing granular flows. We propose a macroscopic model of granular matter based on micropolar fluid dynamics, which incorporates internal rotations, couple stresses, and broken parity through odd viscosity. Our framework extends traditional micropolar theory to describe chiral granular flows driven far from equilibrium, where energy is continuously injected and dissipated. In particular, we focus on steady states and explicitly neglect energy conservation, reflecting the dissipative nature of granular systems maintained in non-equilibrium by external forcing. Within this setup, we study the lift force experienced by a test bead embedded in a compressible, parity-breaking granular flow. We analyze how odd viscosity and microrotation modify the transverse forces, using both analytical results in the linearized Stokes regime and nonlinear finite element simulations. Our results demonstrate that micropolar fluids provide a physically consistent and symmetry-informed continuum description of chiral granular matter, capable of capturing lift forces that emerge uniquely from odd transport effects.
title Lift force in chiral, compressible granular matter
topic Soft Condensed Matter
Fluid Dynamics
url https://arxiv.org/abs/2504.08516