Concentration inequalities for a removal-driven thinning process

Abstract

We prove exponential concentration estimates and a strong law of large numbers for a particle system that is the simplest representative of a general class of models for 2D grain boundary coarsening. The system consists of n particles in (0,∞) that move at unit speed to the left. Each time a particle hits the boundary point 0, it is removed from the system along with a second particle chosen uniformly from the particles in (0,∞). Under the assumption that the initial empirical measure of the particle system converges weakly to a measure with density f0(x) ∈ L1+(0,∞), the empirical measure of the particle system at time t is shown to converge to the measure with density f(x,t), where f is the unique solution to the kinetic equation with nonlinear boundary coupling ∂t f (x,t) - ∂x f(x,t) = -f(0,t)∫0∞ f(y,t)\, dy f(x,t), 0<x < ∞, and initial condition f(x,0)=f0(x). The proof relies on a concentration inequality for an urn model studied by Pittel, and Maurey's concentration inequality for Lipschitz functions on the permutation group.