Static heterogeneity generates apparent universality in first-passage bursty dynamics

Abstract

Processes involving bursts of activity separated by quiescent periods occur across diverse systems and scales. In human dynamics, these phenomena have been described by power-law inter-event time distributions, P(t) t-α, with putative universality classes α=1 and α=32 having been proposed. Whether the observed α = 1 scaling reflects intrinsic scale-free dynamics or instead emerges from heterogeneous underlying rates has been debated at length. We address this question in a canonical physical system for first-passage dynamics: two-dimensional molecular diffusion detected by the tip of a scanning tunnelling microscope. The resulting inter-pulse time distributions exhibit the same apparent truncated power-law form reported for human activities such as email communication, web browsing, and library loans. Maximum-likelihood estimation and model comparison decisively favor a Kohlrausch-Williams-Watts--tempered power law, P(t) t-α(-(t/tc)β), with α 1. Kinetic Monte Carlo simulations reproduce this behavior, showing that the apparent α 1 scaling is confined to a finite time window and arises from tip-induced spatial heterogeneity, not scale invariance.