Optimal Finite-Time Thermodynamics of Effective Two-Level Systems

TL;DR

This paper develops a framework for optimizing finite-time thermodynamics of effective two-level systems, including quantum effects, to maximize work extraction and establish speed limits for transformations.

Contribution

It generalizes previous work to include quantum effects and coarse-graining, providing optimal control protocols and speed limits for effective two-level systems.

Findings

Derived thermodynamically optimal protocols for effective two-level systems.

Established speed limits for transformations of such systems.

Extended analysis to systems with underlying quantum dynamics.

Abstract

The optimization of the conversion of thermal energy into work and the minimization of dissipation for nano- and mesoscopic systems is a complex challenge because of the important role fluctuations play on the dynamics of small systems. We generalize the work of Esposito et al. EPL 89, 20003 (2010) to optimize at all driving speeds the control needed to extract the maximum amount of work from any effective two-level systems. These emerge when one coarse-grains degrees of freedom, which is often unavoidable to obtain "real-world" two-level systems. In particular, we allow even for the system to have underlying quantum dynamics, as long as these allow for a coarse-graining that leads to a Markovian master equation. We analyze the finite-time thermodynamics of these systems and find the thermodynamically optimal protocols, which depend on the size of the coarse-graining needed to obtain a two-level system. Furthermore, we use these results to derive speed-limits for any transformation performed on an effective two-level system.