Diffusion velocity modulus of self-propelled spherical and circular particles in the generalized Langevin approach
Abstract
This research provides a framework for describing the averaged modulus of the velocity reached by an accelerated self-propelled Brownian particle diffusing in a thermal fluid and constrained to a harmonic external potential. The system is immersed in a thermal bath of harmonic oscillators at a constant temperature, where its constituents also interact with the external field. The dynamics is investigated for a sphere and a disk, and is split into two stochastic processes. The first describes the gross-grained inner time-dependent self-velocity generated from a set of independent Ornstein-Uhlenbeck processes without the influence of the external field. This internal mechanism provides the initial velocity for the particle to diffuse in the fluid, which is implemented in a modified generalized Langevin equation as the second process. We find that the system exhibits spontaneous fluctuations in the diffusive velocity modulus due to the inner mechanism; however, as expected, the momentary diffusive velocity fluctuations fade out at large times. The internal propelled velocity module in spherical coordinates is derived, as well as the simulation of the different modules for both the sphere and the already known equations for a disk in polar coordinates.