Programmable Persistent Random Walks in Active Brownian Particles Govern Emergent Dynamics
Abstract
Self-propelled particles serve as minimal models for emulating the dynamic self-organization of microorganisms, yet most synthetic systems remain limited to a single mode of motion, namely active Brownian particles (ABPs). Here, we present an experimental strategy to encode various persistent random walks in ABPs by combining light-modulated propulsion strength with magnetic control of propulsion direction. Our system enables programmable Levy walks with tunable step-length distributions, run-and-tumble dynamics, self-avoiding random walks, and Gaussian walks, with on-demand switching between motion modes within a single experiment. In addition, particles are steered along complex trajectories such as Fibonacci spirals and nested polygons. Beyond single-particle behavior, we show that propulsion modes influence clustering dynamics by comparing ABPs with chiral active particles undergoing circular motion. These results establish a versatile platform for investigating how encoded motion at the level of individual particles governs transport, search strategies, and emergent organization in active matter systems.
Cite
@article{arxiv.2604.26825,
title = {Programmable Persistent Random Walks in Active Brownian Particles Govern Emergent Dynamics},
author = {Tarun Sunkesula Raghavendra and Yogesh Shelke and Stijn van der Ham and Anpuj Nair S and Hanumantha Rao Vutukuri},
journal= {arXiv preprint arXiv:2604.26825},
year = {2026}
}
Comments
Published in Communications Physics (23 March 2026)