Litcius/Paper detail

Random motion of a circle microswimmer in a random environment

Oleksandr Chepizhko, Thomas Franosch

2020New Journal of Physics20 citationsDOIOpen Access PDF

Abstract

Abstract We simulate the dynamics of a single circle microswimmer exploring a disordered array of fixed obstacles. The interplay of two different types of randomness, quenched disorder and stochastic noise, is investigated to unravel their impact on the transport properties. We compute lines of isodiffusivity as a function of the rotational diffusion coefficient and the obstacle density. We find that increasing noise or disorder tends to amplify diffusion, yet for large randomness the competition leads to a strong suppression of transport. We rationalize both the suppression and amplification of transport by comparing the relevant time scales of the free motion to the mean period between collisions with obstacles.

Topics & Concepts

RandomnessStatistical physicsNoise (video)ObstacleDiffusionMotion (physics)PhysicsFunction (biology)Stochastic processStochastic dynamicsRotational diffusionClassical mechanicsComputer scienceMathematicsStatisticsBiologyArtificial intelligenceQuantum mechanicsEvolutionary biologyImage (mathematics)AnisotropyLawPolitical scienceMicro and Nano RoboticsMolecular Communication and NanonetworksMicrofluidic and Bio-sensing Technologies
Random motion of a circle microswimmer in a random environment | Litcius