Optimal Surviving Strategy for Drifted Brownian Motions with Absorption

Abstract

We study the 'Up the River' problem formulated by Aldous (2002), where a unit drift is distributed among a finite collection of Brownian particles on R+ , which are annihilated once they reach the origin. Starting K particles at x=1 , we prove a conjecture of Aldous (2002) that the 'push-the-laggard' strategy of distributing the drift asymptotically (as K∞ ) maximizes the total number of surviving particles, with approximately 4π K1/2 surviving particles. We further establish the hydrodynamic limit of the particle density, in terms of a two-phase PDE with a moving boundary, by utilizing certain integral identities and coupling techniques.