We consider the pressure in the steady-state regime of three stochastic models characterized by self-propulsion and persistent motion and widely employed to describe the behavior of active particles, namely, the Active Brownian particle (ABP) model, the Gaussian colored noise (GCN) model, and the unified colored noise approximation (UCNA) model. Whereas in the limit of short but finite persistence time, the pressure in the UCNA model can be obtained by different methods which have an analog in equilibrium systems, in the remaining two models only the virial route is, in general, possible. According to this method, notwithstanding each model obeys its own specific microscopic law of evolution, the pressure displays a certain universal behavior. For generic interparticle and confining potentials, we derive a formula which establishes a correspondence between the GCN and the UCNA pressures. In order to provide explicit formulas and examples, we specialize the discussion to the case of an assembly of elastic dumbbells confined to a parabolic well. By employing the UCNA we find that, for this model, the pressure determined by the thermodynamic method coincides with the pressures obtained by the virial and mechanical methods. The three methods when applied to the GCN give a pressure identical to that obtained via the UCNA. Finally, we find that the ABP virial pressure exactly agrees with the UCNA and GCN results.

Pressure in an exactly solvable model of active fluid / Marini Bettolo Marconi, Umberto; Maggi, Claudio; Paoluzzi, Matteo. - In: THE JOURNAL OF CHEMICAL PHYSICS. - ISSN 0021-9606. - 147:2(2017). [10.1063/1.4991731]

Pressure in an exactly solvable model of active fluid

Claudio Maggi;Matteo Paoluzzi
2017

Abstract

We consider the pressure in the steady-state regime of three stochastic models characterized by self-propulsion and persistent motion and widely employed to describe the behavior of active particles, namely, the Active Brownian particle (ABP) model, the Gaussian colored noise (GCN) model, and the unified colored noise approximation (UCNA) model. Whereas in the limit of short but finite persistence time, the pressure in the UCNA model can be obtained by different methods which have an analog in equilibrium systems, in the remaining two models only the virial route is, in general, possible. According to this method, notwithstanding each model obeys its own specific microscopic law of evolution, the pressure displays a certain universal behavior. For generic interparticle and confining potentials, we derive a formula which establishes a correspondence between the GCN and the UCNA pressures. In order to provide explicit formulas and examples, we specialize the discussion to the case of an assembly of elastic dumbbells confined to a parabolic well. By employing the UCNA we find that, for this model, the pressure determined by the thermodynamic method coincides with the pressures obtained by the virial and mechanical methods. The three methods when applied to the GCN give a pressure identical to that obtained via the UCNA. Finally, we find that the ABP virial pressure exactly agrees with the UCNA and GCN results.
2017
Active Matter, Soft Matter, Nonequilibrium Statistical Mechanics, Statistical Mechanics, Collective behavior, Phase Transitions
01 Pubblicazione su rivista::01a Articolo in rivista
Pressure in an exactly solvable model of active fluid / Marini Bettolo Marconi, Umberto; Maggi, Claudio; Paoluzzi, Matteo. - In: THE JOURNAL OF CHEMICAL PHYSICS. - ISSN 0021-9606. - 147:2(2017). [10.1063/1.4991731]
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11573/1721368
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