Journal article

Active extensile stress promotes 3D director orientations and flows

Abstract:: We use numerical simulations and linear stability analysis to study an active nematic layer where the director is allowed to point out of the plane. Our results highlight the difference between extensile and contractile systems. Contractile stress suppresses the flows perpendicular to the layer and favors in-plane orientations of the director. By contrast extensile stress promotes instabilities that can turn the director out of the plane, leaving behind a population of distinct, in-plane regions that continually elongate and divide. This supports extensile forces as a mechanism for the initial stages of layer formation in living systems, and we show that a planar drop with extensile (contractile) activity grows into three dimensions (remains in two dimensions). The results also explain the propensity of disclination lines in three dimensional active nematics to be of twist type in extensile or wedge type in contractile materials.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Nejad, M. R., & Yeomans, J. M. (2022). Active extensile stress promotes 3D director orientations and flows. Physical Review Letters, 128(4).

MLA Style

Nejad, M. R., and J. M. Yeomans. “Active Extensile Stress Promotes 3D Director Orientations and Flows.” Physical Review Letters, vol. 128, no. 4, American Physical Society, 2022.

Chicago Style

Nejad, MR, and JM Yeomans. 2022. “Active Extensile Stress Promotes 3D Director Orientations and Flows.” Physical Review Letters 128 (4).
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Files:: Nejad_Yeomans_2022_active_extensile_stress.pdf

(Preview, Accepted manuscript, 2.1MB, Terms of use)

Publisher copy:: 10.1103/physrevlett.128.048001

Authors

+ Nejad, MR More by this author

Role:: Author

+ Yeomans, JM More by this author

Institution:: University of Oxford
Division:: MPLS
Department:: Physics
Sub department:: Theoretical Physics
Oxford college:: St Hilda's College
Role:: Author
ORCID:: 0000-0001-8268-5469

Publisher:: American Physical Society
Journal:: Physical Review Letters More from this journal
Volume:: 128
Issue:: 4
Article number:: 48001
Publication date:: 2022-01-24
Acceptance date:: 2021-12-24
DOI:: 10.1103/physrevlett.128.048001
EISSN:: 1079-7114
ISSN:: 0031-9007
Pmid:: 35148135

Language:: English
Keywords:: FFR
Pubs id:: 1237786
Local pid:: pubs:1237786
Deposit date:: 2022-03-21

Terms of use

Copyright holder:: American Physical Society
Copyright date:: 2022
Rights statement:: © 2022 American Physical Society
Notes:: This is the accepted manuscript version of the article. The final version is available online from American Physical Society at: https://doi.org/10.1103/PhysRevLett.128.048001

Licence:: Terms and Conditions of Use for Oxford University Research Archive

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