Litcius/Paper detail

Escape dynamics of active particles in multistable potentials

Andrei Militaru, Max Innerbichler, Martin Frimmer, Felix Tebbenjohanns, Lukáš Novotný, Christoph Dellago

2021Nature Communications69 citationsDOIOpen Access PDF

Abstract

Rare transitions between long-lived metastable states underlie a great variety of physical, chemical and biological processes. Our quantitative understanding of reactive mechanisms has been driven forward by the insights of transition state theory and in particular by Kramers' dynamical framework. Its predictions, however, do not apply to systems that feature non-conservative forces or correlated noise histories. An important class of such systems are active particles, prominent in both biology and nanotechnology. Here, we study the active escape dynamics of a silica nanoparticle trapped in a bistable potential. We introduce activity by applying an engineered stochastic force that emulates self-propulsion. Our experiments, supported by a theoretical analysis, reveal the existence of an optimal correlation time that maximises the transition rate. We discuss the origins of this active turnover, reminiscent of the much celebrated Kramers turnover. Our work establishes a versatile experimental platform to study single particle dynamics in non-equilibrium settings.

Topics & Concepts

BistabilityMetastabilityStatistical physicsActive matterDynamics (music)NanotechnologyWork (physics)PhysicsDynamical systems theoryBiological systemChemical physicsMaterials scienceBiologyQuantum mechanicsAcousticsCell biologyAdvanced Thermodynamics and Statistical MechanicsMicro and Nano Roboticsstochastic dynamics and bifurcation
Escape dynamics of active particles in multistable potentials | Litcius