arXiv:2007.07419 Abstract | arXiv Analytics

arXiv:2007.07419 [cond-mat.stat-mech]Abstract References Reviews Resources

Scaling of Energy Dissipation in Nonequilibrium Reaction Networks

Published 2020-07-15Version 1

The energy dissipation rate in a nonequilibirum reaction system can be determined by the reaction rates in the underlying reaction network. By developing a coarse-graining process in state space and a corresponding renormalization procedure for reaction rates, we find that energy dissipation rate has an inverse power-law dependence on the number of microscopic states in a coarse-grained state. The dissipation scaling law requires self-similarity of the underlying network, and the scaling exponent depends on the network structure and the flux correlation. Implications of this inverse dissipation scaling law for active flow systems such as microtubule-kinesin mixture are discussed.

Comments: 6 (main text)+ 21 (supplemental information) pages, 4+9 figures, 1 supplemental table

Categories: cond-mat.stat-mech, physics.bio-ph

Keywords: nonequilibrium reaction networks, energy dissipation rate, reaction rates, inverse dissipation scaling law, nonequilibirum reaction system

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