English

Mode selection in compressible active flow networks

Biological Physics 2017-07-19 v2 Soft Condensed Matter Fluid Dynamics

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.

Keywords

Cite

@article{arxiv.1608.07356,
  title  = {Mode selection in compressible active flow networks},
  author = {Aden Forrow and Francis G. Woodhouse and Jörn Dunkel},
  journal= {arXiv preprint arXiv:1608.07356},
  year   = {2017}
}

Comments

new title, several text and figure changes, new results on band gaps added, supplementary information now included

R2 v1 2026-06-22T15:31:36.285Z