Diffusion, subdiffusion and localisation of active colloids in random post lattices
Abstract
Combining experiments and theory, we address the dynamics of self-propelled particles in crowded environments. We first demonstrate that motile colloids cruising at constant speed through random lattices undergo a smooth transition from diffusive, to subdiffusive, to localized dynamics upon increasing the obstacle density. We then elucidate the nature of these transitions by performing extensive simulations constructed from a detailed analysis of the colloid-obstacle interactions. We evidence that repulsion at a distance and hard-core interactions both contribute to slowing down the long-time diffusion of the colloids. In contrast, the localization transition stems solely from excluded-volume interactions and occurs at the void-percolation threshold. Within this critical scenario, equivalent to that of the random Lorentz gas, genuine asymptotic subdiffusion is found only at the critical density where the motile particles explore a fractal maze.
Cite
@article{arxiv.1702.07655,
title = {Diffusion, subdiffusion and localisation of active colloids in random post lattices},
author = {Alexandre Morin and David Lopes Cardozo and Vijayakumar Chikkadi and Denis Bartolo},
journal= {arXiv preprint arXiv:1702.07655},
year = {2017}
}
Comments
9 pages, 8 figures