Simulation of a Brownian particle in an optical trap
Please cite this item using this persistent URLhttp://hdl.handle.net/11693/13240
American Journal of Physics
- Department of Physics 
American Association of Physics Teachers
Unlike passive Brownian particles, active Brownian particles, also known as microswimmers, propel themselves with directed motion and thus drive themselves out of equilibrium. Understanding their motion can provide insight into out-of-equilibrium phenomena associated with biological examples such as bacteria, as well as with artificial microswimmers. We discuss how to mathematically model their motion using a set of stochastic differential equations and how to numerically simulate it using the corresponding set of finite difference equations both in homogenous and complex environments. In particular, we show how active Brownian particles do not follow the Maxwell-Boltzmann distribution-a clear signature of their out-of-equilibrium nature- and how, unlike passive Brownian particles, microswimmers can be funneled, trapped, and sorted. (C) 2014 American Association of Physics Teachers.
Volpe, G., & Volpe, G. (2013). Simulation of a Brownian particle in an optical trap. American Journal of Physics, 81(3), 224-230.