Abstract
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 Matryoshka-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 Matryoshka-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.
Highlights
A diverse range of natural and artificial self-propelled particles are known and are used nowadays
This type of active particles moves with constant speed v0 but their direction changes gradually due to their rotational diffusivity Dr Despite their different moving strategies, run-and-tumble particles (RTPs) and active Brownian particles (ABPs) behave on large length and time scales; like passive Brownian particles (PBP) they exhibit translational diffusion
Using computer simulations to determine mean first-passage times and stationary probability distributions, we demonstrate that ABPs are faster than RTPs in moving from the center to the rim of circular and square mazes, while RTPs reach the center more
Summary
A diverse range of natural and artificial self-propelled particles are known and are used nowadays. According to our simulations and a rate theory, which we developed, ABPs in steady state accumulate in the outermost region of the Matryoshka-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. This type of active particles moves with constant speed v0 but their direction changes gradually due to their rotational diffusivity Dr Despite their different moving strategies, RTPs and ABPs behave on large length and time scales; like passive Brownian particles (PBP) they exhibit translational diffusion.
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