Osmosis with active solutes

Thomas W. Lion; Rosalind J. Allen

doi:10.1209/0295-5075/106/34003

Osmosis with active solutes

Thomas W. Lion^*, Rosalind J. Allen

^*Corresponding author for this work

School of Physics and Astronomy

Research output: Contribution to journal › Article › peer-review

Abstract

Despite much current interest in active matter, little is known about osmosis in active systems. Using molecular dynamics simulations, we investigate how active solutes perturb osmotic steady states. We find that solute activity increases the osmotic pressure, and can also expel solvent from the solution i.e. cause reverse osmosis. The latter effect cannot be described by an effective temperature, but can be reproduced by mapping the active solution onto a passive one with the same degree of local structuring as the passive solvent component. Our results provide a basic framework for understanding active osmosis, and suggest that activity-induced structuring of the passive component may play a key role in the physics of active-passive mixtures. Copyright (C) EPLA, 2014

Original language	English
Article number	34003
Number of pages	6
Journal	European Physical Society Letters (EPL)
Volume	106
Issue number	3
DOIs	https://doi.org/10.1209/0295-5075/106/34003
Publication status	Published - 13 May 2014

Keywords

BROWNIAN PARTICLES
PHASE-SEPARATION
MOLECULAR-DYNAMICS
BACTERIA

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abstract = "Despite much current interest in active matter, little is known about osmosis in active systems. Using molecular dynamics simulations, we investigate how active solutes perturb osmotic steady states. We find that solute activity increases the osmotic pressure, and can also expel solvent from the solution i.e. cause reverse osmosis. The latter effect cannot be described by an effective temperature, but can be reproduced by mapping the active solution onto a passive one with the same degree of local structuring as the passive solvent component. Our results provide a basic framework for understanding active osmosis, and suggest that activity-induced structuring of the passive component may play a key role in the physics of active-passive mixtures. Copyright (C) EPLA, 2014",

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AU - Allen, Rosalind J.

PY - 2014/5/13

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N2 - Despite much current interest in active matter, little is known about osmosis in active systems. Using molecular dynamics simulations, we investigate how active solutes perturb osmotic steady states. We find that solute activity increases the osmotic pressure, and can also expel solvent from the solution i.e. cause reverse osmosis. The latter effect cannot be described by an effective temperature, but can be reproduced by mapping the active solution onto a passive one with the same degree of local structuring as the passive solvent component. Our results provide a basic framework for understanding active osmosis, and suggest that activity-induced structuring of the passive component may play a key role in the physics of active-passive mixtures. Copyright (C) EPLA, 2014

AB - Despite much current interest in active matter, little is known about osmosis in active systems. Using molecular dynamics simulations, we investigate how active solutes perturb osmotic steady states. We find that solute activity increases the osmotic pressure, and can also expel solvent from the solution i.e. cause reverse osmosis. The latter effect cannot be described by an effective temperature, but can be reproduced by mapping the active solution onto a passive one with the same degree of local structuring as the passive solvent component. Our results provide a basic framework for understanding active osmosis, and suggest that activity-induced structuring of the passive component may play a key role in the physics of active-passive mixtures. Copyright (C) EPLA, 2014

KW - BROWNIAN PARTICLES

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KW - MOLECULAR-DYNAMICS

KW - BACTERIA

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SN - 0295-5075

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ER -

Osmosis with active solutes

Abstract

Keywords

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