Statistics of the maximum and the convex hull of a Brownian motion in confined geometries

Abstract

We consider a Brownian particle with diffusion coefficient D in a d-dimensional ball of radius R with reflecting boundaries. We study the maximum Mx(t) of the trajectory of the particle along the x-direction at time t. In the long time limit, the maximum converges to the radius of the ball Mx(t) R for t ∞. We investigate how this limit is approached and obtain an exact analytical expression for the distribution of the fluctuations (t) = [R-Mx(t)]/R in the limit of large t in all dimensions. We find that the distribution of (t) exhibits a rich variety of behaviors depending on the dimension d. These results are obtained by establishing a connection between this problem and the narrow escape time problem. We apply our results in d=2 to study the convex hull of the trajectory of the particle in a disk of radius R with reflecting boundaries. We find that the mean perimeter L(t) of the convex hull exhibits a slow convergence towards the perimeter of the circle 2π R with a stretched exponential decay 2π R- L(t) R(Dt)1/4 \,e-22Dt/R. Finally, we generalise our results to other confining geometries, such as the ellipse with reflecting boundaries. Our results are corroborated by thorough numerical simulations.

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