English

Tracer diffusion in active suspensions

Soft Condensed Matter 2017-05-17 v1

Abstract

We study the diffusion of a Brownian probe particle of size RR in a dilute dispersion of active Brownian particles (ABPs) of size aa, characteristic swim speed U0U_0, reorientation time τR\tau_R, and mechanical energy ksTs=ζaU02τR/6k_s T_s = \zeta_a U_0^2 \tau_R /6, where ζa\zeta_a is the Stokes drag coefficient of a swimmer. The probe has a thermal diffusivity DP=kBT/ζPD_P = k_B T/\zeta_P, where kBTk_B T is the thermal energy of the solvent and ζP\zeta_P is the Stokes drag coefficient for the probe. When the swimmers are inactive, collisions between the probe and the swimmers sterically hinder the probe's diffusive motion. In competition with this steric hindrance is an enhancement driven by the activity of the swimmers. The strength of swimming relative to thermal diffusion is set by Pes=U0a/DPPe_s = U_0 a /D_P. The active contribution to the diffusivity scales as Pes2Pe_s^2 for weak swimming and PesPe_s for strong swimming, but the transition between these two regimes is nonmonotonic. When fluctuations in the probe motion decay on the time scale τR\tau_R, the active diffusivity scales as ksTs/ζPk_s T_s /\zeta_P: the probe moves as if it were immersed in a solvent with energy ksTsk_s T_s rather than kBTk_B T.

Keywords

Cite

@article{arxiv.1703.10554,
  title  = {Tracer diffusion in active suspensions},
  author = {Eric W. Burkholder and John F. Brady},
  journal= {arXiv preprint arXiv:1703.10554},
  year   = {2017}
}

Comments

5 pages, 3 figures, submitted for publication. Please contact authors regarding supplemental information

R2 v1 2026-06-22T19:02:29.896Z