Impact of periodic thermal driving on heat fluctuations in a harmonic system

Abstract

The thermodynamics of mesoscopic systems driven by time-varying temperatures is crucial for understanding biological systems, designing nanoscale engines, and performing micro-particle cooling. In this work, we analyze an underdamped Brownian particle in a harmonic trap under a sinusoidal thermal protocol. Through analytical methods and numerical simulations, we analyze the system's dynamics and heat statistics. We report the emergence of resonant position-velocity correlations and a non-Gaussian, asymmetric heat distribution consistent with the Fluctuation Theorem. We demonstrate that inertia is a key parameter, damping the system's response and slowing its relaxation to a periodic non-equilibrium steady state. Our results show that oscillatory thermal driving is a powerful tool for controlling nanoscale energy flow.