Non-Gaussian diffusion in static disordered media.
Non-Gaussian diffusion is commonly considered as a result of fluctuating diffusivity, which is correlated in time or in space or both. In this work, we investigate the non-Gaussian diffusion in static disordered media via a quenched trap model, where the diffusivity is spatially correlated. Several unique effects due to quenched disorder are reported. We analytically estimate the diffusion coefficient $D_{\text{dis}}$ and its fluctuation over samples of finite size. We show a sharp peak in the distribution of displacement $P(x,t)$ around $x=0$, that has frequently been observed in experiments, but not previously explained theoretically. We examine the fidelity of the coarse-grained diffusion map, which is reconstructed from particle trajectories. Finally, we propose a procedure to estimate the correlation length in static disordered environments, where the information stored in the sample-to-sample fluctuation has been utilized.
Publisher URL: http://arxiv.org/abs/1712.00569
DOI: arXiv:1712.00569v2
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