English

Is subdiffusional transport slower than normal?

Statistical Mechanics 2014-09-24 v1

Abstract

We consider anomalous non-Markovian transport of Brownian particles in viscoelastic fluid-like media with very large but finite macroscopic viscosity under the influence of a constant force field F. The viscoelastic properties of the medium are characterized by a power-law viscoelastic memory kernel which ultra slow decays in time on the time scale \tau of strong viscoelastic correlations. The subdiffusive transport regime emerges transiently for t<\tau. However, the transport becomes asymptotically normal for t>>\tau. It is shown that even though transiently the mean displacement and the variance both scale sublinearly, i.e. anomalously slow, in time, <\delta x(t)> ~ F t^\alpha, <\delta x^2(t)> ~ t^\alpha, 0<\alpha<1, the mean displacement at each instant of time is nevertheless always larger than one obtained for normal transport in a purely viscous medium with the same macroscopic viscosity obtained in the Markovian approximation. This can have profound implications for the subdiffusive transport in biological cells as the notion of "ultra-slowness" can be misleading in the context of anomalous diffusion-limited transport and reaction processes occurring on nano- and mesoscales.

Keywords

Cite

@article{arxiv.1201.5308,
  title  = {Is subdiffusional transport slower than normal?},
  author = {Igor Goychuk},
  journal= {arXiv preprint arXiv:1201.5308},
  year   = {2014}
}
R2 v1 2026-06-21T20:09:37.526Z