Active Brownian particles and run-and-tumble particles separate inside a maze

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<jats:title>Abstract</jats:title><jats:p>A diverse range of natural and artificial self-propelled particles are known and are used nowadays. Among them, active Brownian particles (ABPs) and run-and-tumble particles (RTPs) are two important classes. We numerically study non-interacting ABPs and RTPs strongly confined to different maze geometries in two dimensions. We demonstrate that by means of geometrical confinement alone, ABPs are separable from RTPs. By investigating <jats:italic>Matryoshka</jats:italic>-like mazes with nested shells, we show that a circular maze has the best filtration efficiency. Results on the mean first-passage time reveal that ABPs escape faster from the center of the maze, while RTPs reach the center from the rim more easily. According to our simulations and a rate theory, which we developed, ABPs in steady state accumulate in the outermost region of the <jats:italic>Matryoshka</jats:italic>-like mazes, while RTPs occupy all locations within the maze with nearly equal probability. These results suggest a novel technique for separating different types of self-propelled particles by designing appropriate confining geometries without using chemical or biological agents.</jats:p>

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  • Scientific Reports

    Scientific Reports 6 (1), 2016-11-23

    Springer Science and Business Media LLC

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