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Thermal fluctuations for a three-beads swimmer

Thermal fluctuations for a three-beads swimmer
Thermal fluctuations for a three-beads swimmer
We discuss a micro-swimmer model made of three spheres actuated by an internal active time-periodic force, tied by an elastic potential and submitted to hydrodynamic interactions with thermal noise. The dynamical approach we use, replacing the more common kinetic one, unveils the instability of the original model and the need of a confining potential to prevent the evaporation of the swimmer. We investigate the effect of the main parameters of the model, such as the frequency and phase difference of the periodic active force, the stiffness of the confining potential, the length of the swimmer and the temperature and viscosity of the fluid. Our observables of interest are the averages of the swim velocity, of the energy consumption rate, the diffusion coefficient and the swimming precision, which is limited by the energy consumption through the celebrated Thermodynamic Uncertainty Relations. An optimum for velocity and precision is found for an intermediate frequency. Reducing the potential stiffness, the viscosity or the length, is also beneficial for the swimming performance, but these parameters are limited by the consistency of the model. Analytical approximation for many of the interesting observables is obtained for small deformations of the swimmer. We also discuss the efficiency of the swimmer in terms of its maximum precision and of the hydrodynamic, or Lighthill, criterion, and how they are connected.
cond-mat.soft, cond-mat.stat-mech
Ferretta, R.
b7be9b58-4cca-4a68-b9ac-101a296cd08b
Leonardo, R. Di
95806f9e-2b7e-4ae7-904f-afe318d1bd4e
Puglisi, A.
97237841-1e6d-48fb-9133-671b6f3af18b
Ferretta, R.
b7be9b58-4cca-4a68-b9ac-101a296cd08b
Leonardo, R. Di
95806f9e-2b7e-4ae7-904f-afe318d1bd4e
Puglisi, A.
97237841-1e6d-48fb-9133-671b6f3af18b

[Unknown type: UNSPECIFIED]

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Abstract

We discuss a micro-swimmer model made of three spheres actuated by an internal active time-periodic force, tied by an elastic potential and submitted to hydrodynamic interactions with thermal noise. The dynamical approach we use, replacing the more common kinetic one, unveils the instability of the original model and the need of a confining potential to prevent the evaporation of the swimmer. We investigate the effect of the main parameters of the model, such as the frequency and phase difference of the periodic active force, the stiffness of the confining potential, the length of the swimmer and the temperature and viscosity of the fluid. Our observables of interest are the averages of the swim velocity, of the energy consumption rate, the diffusion coefficient and the swimming precision, which is limited by the energy consumption through the celebrated Thermodynamic Uncertainty Relations. An optimum for velocity and precision is found for an intermediate frequency. Reducing the potential stiffness, the viscosity or the length, is also beneficial for the swimming performance, but these parameters are limited by the consistency of the model. Analytical approximation for many of the interesting observables is obtained for small deformations of the swimmer. We also discuss the efficiency of the swimmer in terms of its maximum precision and of the hydrodynamic, or Lighthill, criterion, and how they are connected.

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2311.13302v1 - Author's Original
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e-pub ahead of print date: 22 November 2023
Additional Information: 17 pages, 18 figures, submitted
Keywords: cond-mat.soft, cond-mat.stat-mech

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Local EPrints ID: 487415
URI: http://eprints.soton.ac.uk/id/eprint/487415
PURE UUID: 1a8d3709-7ace-46c9-b2d5-8f5df0d5ed82

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Date deposited: 20 Feb 2024 12:47
Last modified: 11 Jun 2024 23:59

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Contributors

Author: R. Ferretta
Author: R. Di Leonardo
Author: A. Puglisi

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