Abstract
We study, by extensive numerical simulations, the dynamics of a hard-core tracer particle (TP) in presence of two competing types of disorder—frozen convection flows on a square random Manhattan lattice and a crowded dynamical environment formed by a lattice gas of mobile hard-core particles. The latter perform lattice random walks, constrained by a single-occupancy condition of each lattice site, and are either insensitive to random flows (model A) or choose the jump directions as dictated by the local directionality of bonds of the random Manhattan lattice (model B). We focus on the TP disorder-averaged mean-squared displacement, (which shows a super-diffusive behaviour ∼t4/3, t being time, in all the cases studied here), on higher moments of the TP displacement, and on the probability distribution of the TP position X along the x-axis, for which we unveil a previously unknown behaviour. Indeed, our analysis evidences that in absence of the lattice gas particles the latter probability distribution has a Gaussian central part , where u = X/t2/3, and exhibits slower-than-Gaussian tails for sufficiently large t and u. Numerical data convincingly demonstrate that in presence of a crowded environment the central Gaussian part and non-Gaussian tails of the distribution persist for both models.
Highlights
In many realistic systems encountered across several disciplines—e.g. physics, chemistry, molecular and cellular biology,random motion of tracer particles takes place in presence of disorder, either temporal or spatial, which may originate from a variety of different factors [1,2,3,4,5,6,7,8,9,10,11,12,13]
We study here by extensive numerical simulations the dynamics of a tracer particle (TP) which evolves on a square random Manhattan lattice of frozen convection flows in presence of a lattice gas (LG) of mobile hard-core particles
We studied the tracer particle (TP) dynamics in presence of two interspersed and competing types of disorder—quenched random convection flows on a random Manhattan lattice, which prompt the TP to move super-diffusively, and a crowded dynamical environment formed by a lattice gas (LG) of hard-core particles, which hinder the TP motion
Summary
Institut für Theoretische Physik, Universität Stuttgart, Pfaffenwaldring 57, D-70569 Stuttgart, Germany 7 Author to whom any correspondence should be addressed. By extensive numerical simulations, the dynamics of a hard-core tracer particle (TP) in author(s) and the title of the work, journal citation presence of two competing types of disorder—frozen convection flows on a square random Manhattan and DOI. Lattice and a crowded dynamical environment formed by a lattice gas of mobile hard-core particles. The latter perform lattice random walks, constrained by a single-occupancy condition of each lattice site, and are either insensitive to random flows (model A) or choose the jump directions as dictated by the local directionality of bonds of the random Manhattan lattice (model B). Numerical data convincingly demonstrate that in presence of a crowded environment the central Gaussian part and non-Gaussian tails of the distribution persist for both models
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