Added mass effect in coupled Brownian particles
Abstract
The added mass effect is the contribution to a Brownian particle's effective mass arising from the hydrodynamic flow its motion induces. For a spherical particle in an incompressible fluid, the added mass is half the fluid's displaced mass, but in a compressible fluid its value depends on a competition between timescales. Here we illustrate this behavior with a solvable model of two harmonically coupled Brownian particles of mass , one representing the sphere, the other the immediately surrounding fluid. The measured distribution of the Brownian particle's velocity, , follows a Maxwell-Boltzmann distribution with an effective mass . Solving analytically for , we find that its value is determined by three relevant timescales: the momentum relaxation time, , the harmonic oscillation period, , and the velocity measurement time resolution, . In limiting cases and , our expression for reduces to and , respectively. We find similar behavior upon generalizing the model to the case of unequal masses.
Cite
@article{arxiv.2405.01696,
title = {Added mass effect in coupled Brownian particles},
author = {Long Him Cheung and Christopher Jarzynski},
journal= {arXiv preprint arXiv:2405.01696},
year = {2024}
}
Comments
13 pages, 5 figures