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arxiv: 2007.02947 · v1 · pith:DXISHCFDnew · submitted 2020-07-06 · ❄️ cond-mat.soft · physics.bio-ph

Multi-defect Dynamics in Active Nematics

classification ❄️ cond-mat.soft physics.bio-ph
keywords dynamicsactivedefectsnematicsdefectcollectivecoupledeffective
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Recent experiments and numerical studies have drawn attention to the dynamics of active nematics. Two-dimensional active nematics flow spontaneously and exhibit spatiotemporal chaotic flows with proliferation of topological defects in the nematic texture. It has been proposed that the dynamics of active nematics can be understood in terms of the dynamics of interacting defects, propelled by active stress. Previous work has derived effective equations of motion for individual defects as quasi-particles moving in the mean field generated by other defects, but an effective theory governing multi-defect dynamics has remained out of reach. In this paper, we examine the dynamics of 2D active nematics in the limit of strong order and overdamped compressible flow. The activity-induced defect dynamics is formulated as a perturbation of the manifold of quasi-static nematic textures explicitly parameterized by defect positions. This makes it possible to derive a set of coupled ordinary differential equations governing defect (and therefore texture) dynamics. Interestingly, because of the non-orthogonality of textures associated with individual defects, their motion is coupled through a position dependent ``collective mobility" matrix. In addition to the familiar active self-propulsion of the $+1/2$ defect, we obtain new collective effects of activity that can be interpreted in terms of non-central and non-reciprocal interactions between defects.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Epithelia Realize Nematopolar Topological Defect Structures

    cond-mat.soft 2026-06 unverdicted novelty 6.0

    Epithelial monolayers realize a mixed polar-nematic phase with coexisting ±1 and ±1/2 topological defects driven by active stresses and polar-nematic elasticity.