Stretched exponential decay for subcritical parking times on Zd

Abstract

In the parking model on Zd, each vertex is initially occupied by a car (with probability p) or by a vacant parking spot (with probability 1-p). Cars perform independent random walks and when they enter a vacant spot, they park there, thereby rendering the spot occupied. Cars visiting occupied spots simply keep driving (continuing their random walk). It is known that p=1/2 is a critical value in the sense that the origin is a.s. visited by finitely many distinct cars when p<1/2, and by infinitely many distinct cars when p≥ 1/2. Furthermore, any given car a.s. eventually parks for p ≤ 1/2 and with positive probability does not park for p > 1/2. We study the subcritical phase and prove that the tail of the parking time τ of the car initially at the origin obeys the bounds \[ ( - C1 tdd+2) ≤ Pp(τ > t) ≤ ( - c2 tdd+2) \] for p>0 sufficiently small. For d=1, we prove these inequalities for all p ∈ [0,1/2). This result presents an asymmetry with the supercritical phase (p>1/2), where methods of Bramson--Lebowitz imply that for d=1 the corresponding tail of the parking time of the parking spot of the origin decays like e-ct. Our exponent d/(d+2) also differs from those previously obtained in the case of moving obstacles.