Mean-squared displacement and variance for confined Brownian motion

Abstract

For one-dimension Brownian motion in the confined system with the size L, the mean-squared displacement(MSD) defined by (x-x0)2 should be proportional to tα(t). The power α(t) should range from 1 to 0 over time, and the MSD turns from 2Dt to c L2, here the coefficient c independent of t, D being the diffusion coefficient. The paper aims to quantitatively solve the MSD in the intermediate confinement regime. The key to this problem is how to deal with the propagator and the normalization factor of the Fokker-Planck equation(FPE) with the Dirichlet Boundaries. Applying the Euler-Maclaurin approximation(EMA) and integration by parts for the small t, we obtain the MSD being 2Dt(1-2 3ππ), with tch=L24π2D, ttch, and the power α(t) being 1-0.181-0.12. Further, we analysis the MSD and the power for the d-dimension system with γ-dimension confinement. In the case of γ< d, there exists the sub-diffusive behavior in the intermediate time. The universal description is consistent with the recent experiments and simulations in the micro-nano systems. Finally, we calculate the position variance(PV) meaning (x- x )2 . Under the initial condition referring to the different probability density function(PDF) being p0(x), MSD and PV should exhibit different dependencies on time, which reflect corresponding diffusion behaviors.As examples, the paper discusses the representative initial PDFs reading p0(x)=δ(x-x0), with the midpoint x0=L2 and the endpoint x0=ε(or 0+).The MSD(equal to PV) reads 2Dt(1-5π3 DtL2),and 4π(2Dt)[1+2π DtL]for the small t,respectively.