KPZ physics and phase transition in a classical single random walker under continuous measurement

Abstract

We introduce and study a new model consisting of a single classical random walker undergoing continuous monitoring at rate γ on a discrete lattice. Although such a continuous measurement cannot affect physical observables, it has a non-trivial effect on the probability distribution of the random walker. At small γ, we show analytically that the time-evolution of the latter can be mapped to the Stochastic Heat Equation (SHE). In this limit, the width of the log probability thus follows a Family-Vicsek scaling law, Nαf(t/Nα/β), with roughness and growth exponents corresponding to the Kardar-Parisi-Zhang (KPZ) universality class, i.e α1DKPZ=1/2 and β1DKPZ=1/3 respectively. When γ is increased outside this regime, we find numerically in 1D a crossover from the KPZ class to a new universality class characterized by exponents α1DM≈ 1 and β1DM≈ 1.4. In 3D, varying γ beyond a critical value γcM leads to a phase transition from a smooth phase that we identify as the Edwards-Wilkinson (EW) class to a new universality class with α3DM≈1.