Dynamics of Brownian particles in asymmetric confinement: Insights into Entropic Stochastic Resonance

Abstract

We explore the effect of asymmetry in the thermodynamic response (work done) of an overdamped Brownian system driven by a time-periodic field when the particle is confined inside a bilobal irregular structure. The spatial irregularity of the asymmetric confinement results in an effective asymmetric entropic bistable potential along the direction of transport. We investigate how the frequency of the periodic field and the intensity of the noise impact the average work done, focusing on its potential as a key metric for examining Entropic Stochastic Resonance (ESR). The study highlights the impact of confinement asymmetry on reducing the average work done. Furthermore, we observe a transition of average work done from a state dominated by energy to one dominated by entropy, as we manipulate the magnitude of the transverse force. In addition, an alternative quantity called the mean free flight time (TMFFT) is proposed to describe the ESR in the presence of asymmetry.