Unlocking inaccessible performance of the quantum refrigerator with catalysts

TL;DR

This paper demonstrates that incorporating a catalyst into a two-stroke quantum refrigerator significantly enhances its performance, allowing it to surpass traditional thermodynamic bounds and operate in previously inaccessible regimes.

Contribution

The study extends catalytic enhancement concepts to quantum refrigerators, showing improved COP and operational range beyond the Otto bound with a catalyst that remains unchanged after cycles.

Findings

Catalyst enables COP and cooling capacity to exceed Otto bound.

Refrigerator operates in new frequency and temperature regimes with catalyst.

Two permutation types are needed to enhance COP and operational range.

Abstract

Quantum thermal machines offer promising platforms for exploring the fundamental limits of thermodynamics at the microscopic scale. The previous study demonstrated that the incorporation of a catalyst can significantly enhance the performance of a heat engine by broadening its operational regime and achieving a more favorable trade-off between work output and efficiency. Building on this powerful framework and innovative idea, here we further extend the concept to a two-stroke quantum refrigerator that extracts heat from a cold reservoir via discrete strokes powered by external work. The working medium consists of two two-level systems (TLSs) and two heat reservoirs at different temperatures and is assisted by an auxiliary system acting as a catalyst. Remarkably, the catalyst remains unchanged after each cycle, ensuring that heat extraction is driven entirely by the work input. We show that the presence of the catalyst leads to two significant enhancements: it enables the coefficient of performance (COP) and cooling capacity to exceed the Otto bound and allows the refrigerator to operate in frequency and temperature regimes that are inaccessible without a catalyst. Furthermore, through a comparison with catalytic heat engines, our analysis reveals that two distinct permutation types are necessary to simultaneously enhance the COP and operational range of refrigerators, in contrast to heat engines for which a single permutation suffices. These results highlight the potential of catalytic mechanisms to broaden the operational capabilities of quantum thermal devices and to surpass conventional thermodynamic performance limits.