Litcius/Paper detail

Crowding-Enhanced Diffusion: An Exact Theory for Highly Entangled Self-Propelled Stiff Filaments

Suvendu Mandal, Christina Kurzthaler, Thomas Franosch, Hartmut Löwen

2020Physical Review Letters32 citationsDOIOpen Access PDF

Abstract

We study a strongly interacting crowded system of self-propelled stiff filaments by event-driven Brownian dynamics simulations and an analytical theory to elucidate the intricate interplay of crowding and self-propulsion. We find a remarkable increase of the effective diffusivity upon increasing the filament number density by more than one order of magnitude. This counterintuitive "crowded is faster" behavior can be rationalized by extending the concept of a confining tube pioneered by Doi and Edwards for highly entangled, crowded, passive to active systems. We predict a scaling theory for the effective diffusivity as a function of the Péclet number and the filament number density. Subsequently, we show that an exact expression derived for a single self-propelled filament with motility parameters as input can predict the nontrivial spatiotemporal dynamics over the entire range of length and timescales. In particular, our theory captures short-time diffusion, directed swimming motion at intermediate times, and the transition to complete orientational relaxation at long times.

Topics & Concepts

PhysicsProtein filamentBrownian motionDiffusionStatistical physicsRelaxation (psychology)ScalingClassical mechanicsQuantum mechanicsMaterials scienceSocial psychologyMathematicsComposite materialPsychologyGeometryMicro and Nano RoboticsAdvanced Thermodynamics and Statistical MechanicsMolecular Communication and Nanonetworks