Diffusion with stochastic resetting on a lattice

Abstract

We provide an exact formula for the mean first-passage time (MFPT) to a target at the origin for a single particle diffusing on a d-dimensional hypercubic lattice starting from a fixed initial position R0 and resetting to R0 with a rate r. Previously known results in the continuous space are recovered in the scaling limit r 0, R0=| R0| ∞ with the product r\, R0 fixed. However, our formula is valid for any r and any R0 that enables us to explore a much wider region of the parameter space that is inaccessible in the continuum limit. For example, we have shown that the MFPT, as a function of r for fixed R0, diverges in the two opposite limits r 0 and r ∞ with a unique minimum in between, provided the starting point is not a nearest neighbour of the target. In this case, the MFPT diverges as a power law rφ as r ∞, but very interestingly with an exponent φ= (|m1|+|m2|+… +|md|)-1 that depends on the starting point R0= a\, (m1,m2,…, md) where a is the lattice spacing and mi's are integers. If, on the other hand, the starting point happens to be a nearest neighbour of the target, then the MFPT decreases monotonically with increasing r, approaching a universal limiting value 1 as r ∞, indicating that the optimal resetting rate in this case is infinity. We provide a simple physical reason and a simple Markov-chain explanation behind this somewhat unexpected universal result. Our analytical predictions are verified in numerical simulations on lattices up to 50 dimensions. Finally, in the absence of a target, we also compute exactly the position distribution of the walker in the nonequlibrium stationary state that also displays interesting lattice effects not captured by the continuum theory.