Journal article

Mode selection in compressible active flow networks

Abstract:: Coherent, large-scale dynamics in many nonequilibrium physical, biological, or information transport networks are driven by small-scale local energy input. Here, we introduce and explore an analytically tractable nonlinear model for compressible active flow networks. In contrast to thermally driven systems, we find that active friction selects discrete states with a limited number of oscillation modes activated at distinct fixed amplitudes. Using perturbation theory, we systematically predict the stationary states of noisy networks and find good agreement with a Bayesian state estimation based on a hidden Markov model applied to simulated time series data. Our results suggest that the macroscopic response of active network structures, from actomyosin force networks to cytoplasmic flows, can be dominated by a significantly reduced number of modes, in contrast to energy equipartition in thermal equilibrium. The model is also well suited to study topological sound modes and spectral band gaps in active matter.

Publication status:: Published

Peer review status:: Peer reviewed

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APA Style

Forrow, A., Woodhouse, F., & Dunkel, J. (2017). Mode selection in compressible active flow networks. Physical Review Letters, 119(2).

MLA Style

Forrow, A., et al. “Mode Selection in Compressible Active Flow Networks.” Physical Review Letters, vol. 119, no. 2, American Physical Society, 2017.

Chicago Style

Forrow, A, F Woodhouse, and J Dunkel. 2017. “Mode Selection in Compressible Active Flow Networks.” Physical Review Letters 119 (2).
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Files:: 2017Forrow.pdf

(Preview, Accepted manuscript, pdf, 2.6MB, Terms of use)

supplemental.zip

(Accepted manuscript, zip, 33.4MB, Terms of use)

Publisher copy:: 10.1103/physrevlett.119.028102

Authors

+ Forrow, A More by this author

Institution:: University of Oxford
Division:: MPLS Division
Department:: Mathematical Institute
Role:: Author

+ Woodhouse, F More by this author

Institution:: University of Oxford
Division:: MPLS Division
Department:: Mathematical Institute
Department:: Unknown
Role:: Author
ORCID:: 0000-0002-5305-5510

+ Dunkel, J More by this author

Role:: Author
ORCID:: 0000-0001-8865-2369

Publisher:: American Physical Society
Journal:: Physical Review Letters More from this journal
Volume:: 119
Issue:: 2
Article number:: 028102
Publication date:: 2017-07-14
Acceptance date:: 2017-06-12
DOI:: 10.1103/physrevlett.119.028102
EISSN:: 1079-7114
ISSN:: 0031-9007
Pmid:: 28753360

Language:: English
Pubs id:: pubs:940508
UUID:: uuid:6fcdf340-29c1-4977-8722-ff622a5c4e3f
Local pid:: pubs:940508
Source identifiers:: 940508
Deposit date:: 2019-01-18

Terms of use

Copyright holder:: American Physical Society
Copyright date:: 2017
Notes:: Copyright © 2017 American Physical Society. 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.119.028102

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

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