Spontaneous self-constraint in active nematic flows

Active processes drive biological dynamics across various scales and include subcellular cytoskeletal remodelling, tissue development in embryogenesis and the population-level expansion of bacterial colonies. In each of these, biological functionality requires collective flows to occur while self-or...

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Bibliographic Details
Published in:Nature physics 2024-03, Vol.20 (3), p.492-500
Main Authors: Head, Louise C., Doré, Claire, Keogh, Ryan R., Bonn, Lasse, Negro, Giuseppe, Marenduzzo, Davide, Doostmohammadi, Amin, Thijssen, Kristian, López-León, Teresa, Shendruk, Tyler N.
Format: Article
Language:English
Subjects:
639/301/923/614
639/301/923/919
639/766/747
Active control
Atomic
Biological activity
Biomimetic materials
Biomimetics
Classical and Continuum Physics
Complex Systems
Condensed Matter Physics
Constraints
Coupling
Defects
Dynamic control
Dynamic structural analysis
Dynamics
Elongated structure
Embryonic growth stage
Mathematical and Computational Physics
Mesoscale phenomena
Microscopy
Molecular
Motion picture directors & producers
Optical and Plasma Physics
Physics
Physics and Astronomy
Simulation
Strain rate
Swirling
Theoretical
Velocity
Vortices
Vorticity
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Summary:Active processes drive biological dynamics across various scales and include subcellular cytoskeletal remodelling, tissue development in embryogenesis and the population-level expansion of bacterial colonies. In each of these, biological functionality requires collective flows to occur while self-organised structures are protected. However, the mechanisms by which active flows can spontaneously constrain their dynamics to preserve structure are not known. Here, by studying collective flows and defect dynamics in active nematic films, we demonstrate the existence of a self-constraint, namely a two-way, spontaneously arising relationship between activity-driven isosurfaces of flow boundaries and mesoscale nematic structures. We show that self-motile defects are tightly constrained to viscometric surfaces, which are contours along which the vorticity and the strain rate are balanced. This in turn reveals that self-motile defects break mirror symmetry when they move along a single viscometric surface. This is explained by an interdependence between viscometric surfaces and bend walls, which are elongated narrow kinks in the orientation field. These findings indicate that defects cannot be treated as solitary points. Instead, their associated mesoscale deformations are key to the steady-state coupling to hydrodynamic flows. This mesoscale cross-field self-constraint offers a framework for tackling complex three-dimensional active turbulence, designing dynamic control into biomimetic materials and understanding how biological systems can employ active stress for dynamic self-organisation. Active flows in biological systems swirl. A coupling between active flows, elongated deformations and defect dynamics helps preserve self-organised structures against disordered swirling.
ISSN:1745-2473
1745-2481
DOI:10.1038/s41567-023-02336-5