Issue 30, 2022

Model for active particles confined in a two-state micropattern

Abstract

We propose a model, based on active Brownian particles, for the dynamics of cells confined in a two-state micropattern, composed of two rectangular boxes connected by a bridge, and investigate the transition statistics. A transition between boxes occurs when the active particle crosses the center of the bridge, and the time between subsequent transitions is the dwell time. By assuming that the rotational diffusion time τ is a function of the position, some experimental observations are qualitatively recovered as, for example, the shape of the survival function. τ controls the transition from a ballistic regime at short time scales to a diffusive regime at long time scales, with an effective diffusion coefficient proportional to τ. For small values of τ, the dwell time is determined by the characteristic diffusion timescale which is constant for very low values of τ, when the rotational diffusion is much faster than the translational one and decays with τ for intermediate values of τ. For large values of τ, the interaction with the walls dominates and the particle stays mostly at the corners of the boxes increasing the dwell time. We find that there is an optimal τ for which the dwell time is minimal and its value can be tuned by changing the geometry of the pattern.

Graphical abstract: Model for active particles confined in a two-state micropattern

Article information

Article type
Paper
Submitted
11 May 2022
Accepted
17 Jul 2022
First published
18 Jul 2022

Soft Matter, 2022,18, 5699-5705

Model for active particles confined in a two-state micropattern

F. M. R. Safara, H. P. M. Melo, M. M. Telo da Gama and N. A. M. Araújo, Soft Matter, 2022, 18, 5699 DOI: 10.1039/D2SM00616B

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