Hyperdiffusion of Poissonian run-and-tumble particles in two dimensions

Abstract

We study non-interacting Poissonian run-and-tumble particles (RTPs) in two dimensions whose velocity orientations are controlled by an arbitrary circular distribution Q(φ). RTP-type active transport has been reported to undergo localization inside crowded and disordered environments, yet its non-equilibrium dynamics, especially at intermediate times, has not been elucidated analytically. Here, starting from the standard (one-state) RTPs, we formulate the localized (two-state) RTPs by concatenating an overdamped Brownian motion in a Markovian manner. Using the space-time coupling technique in continuous-time random walk theory, we generalize the Montroll-Weiss formula in a decomposable form over the Fourier coefficient Q and reveal that the displacement moment r2μ(t) depends on finite angular moments Q for ||≤ μ. Based on this finding, we provide (i) the angular distribution of velocity reorientation for one-state RTPs and (ii) r2(t) over all timescales for two-state RTPs. In particular, we find the intricate time evolution of r2(t) that depends on initial dynamic states and, remarkably, detect hyperdiffusive scaling r2(t) tβ(t) with an anomalous exponent 2<β(t)≤ 3 in the short- and intermediate-time regimes. Our work suggests that the localization emerging within complex systems can increase the dispersion rate of active transport even beyond the ballistic limit.