Issue 41, 2023

Dynamic phases and combing effects for elongated particles moving over quenched disorder

Abstract

We consider a two-dimensional system of elongated particles driven over a landscape containing randomly placed pinning sites. For varied pinning site density, external drive magnitude, and particle elongation, we find a wide variety of dynamic phases, including random structures, stripe or combed phases with nematic order, and clogged states. The different regimes can be identified by examining nematic ordering, cluster size, number of pinned particles, and transverse diffusion. In some regimes we find that the pinning can enhance the particle alignment, producing a nonmonotonic signature in the nematic ordering with a maximum at a particular combination of pinning density and drive. The optimal nematic occurs when a sufficient number of particles can be pinned, generating a local shear and leading to what we call a combing effect. At high drives, the combing effect is reduced when the number of pinned particles decreases. For stronger pinning, the particles form a heterogeneous clustered or clogged state that depins into a fluctuating state with high diffusion.

Graphical abstract: Dynamic phases and combing effects for elongated particles moving over quenched disorder

Supplementary files

Article information

Article type
Paper
Submitted
03 Aug 2023
Accepted
29 Sep 2023
First published
29 Sep 2023
This article is Open Access
Creative Commons BY-NC license

Soft Matter, 2023,19, 7937-7943

Dynamic phases and combing effects for elongated particles moving over quenched disorder

A. Libál, S. Stepanov, C. Reichhardt and C. J. O. Reichhardt, Soft Matter, 2023, 19, 7937 DOI: 10.1039/D3SM01034A

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