Active viscoelastic matter: from bacterial drag reduction to turbulent solids

Active viscoelastic matter: from bacterial drag reduction to turbulent solids

A paradigm for internally driven matter is the active nematic liquid crystal, whereby the equations of a conventional nematic are supplemented by a minimal active stress that violates time-reversal symmetry. In practice, active fluids may have not only liquid-crystalline but also viscoelastic polyme...

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Veröffentlicht in:Physical review letters 2015-03, Vol.114 (9), p.098302-098302, Article 098302
Hauptverfasser: Hemingway, E J, Maitra, A, Banerjee, S, Marchetti, M C, Ramaswamy, S, Fielding, S M, Cates, M E
Format: Artikel
Sprache:eng
Schlagworte:
Bacteria
Bacteria - chemistry
Bacterial Physiological Phenomena
Computational fluid dynamics
Fluid flow
Liquid Crystals - chemistry
Mathematical analysis
Models, Biological
Models, Chemical
Nematic
Rheology - methods
Spontaneous
Swimming
Turbulence
Turbulent flow
Viscoelastic Substances - chemistry
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Zusammenfassung:A paradigm for internally driven matter is the active nematic liquid crystal, whereby the equations of a conventional nematic are supplemented by a minimal active stress that violates time-reversal symmetry. In practice, active fluids may have not only liquid-crystalline but also viscoelastic polymer degrees of freedom. Here we explore the resulting interplay by coupling an active nematic to a minimal model of polymer rheology. We find that adding a polymer can greatly increase the complexity of spontaneous flow, but can also have calming effects, thereby increasing the net throughput of spontaneous flow along a pipe (a "drag-reduction" effect). Remarkably, active turbulence can also arise after switching on activity in a sufficiently soft elastomeric solid.
ISSN:0031-9007
1079-7114
DOI:10.1103/PhysRevLett.114.098302