Subdiffusivity of Brownian motion among a Poissonian field of moving traps

Abstract

Our model consists of a Brownian particle X moving in R, where a Poissonian field of moving traps is present. Each trap is a ball with constant radius, centered at a trap point, and each trap point moves under a Brownian motion independently of others and of the motion of X. Here, we investigate the 'speed' of X on the time interval [0,t] and on 'microscopic' time scales given that X avoids the trap field up to time t. Firstly, following the earlier work of Athreya et al. [Math. Phys. Anal. Geom. 20:1 (2017)], we obtain bounds on the maximal displacement of X from the origin. Our upper bound is an improvement of the corresponding bound therein. Then, we prove a result showing how the speed on microscopic time scales affect the overall macroscopic subdiffusivity on [0,t]. Finally, we show that X moves subdiffusively even on certain microscopic time scales, in the bulk of [0,t]. The results are stated so that each gives an 'optimal survival strategy' for the system. We conclude by giving several related open problems.