Minimal quantum thermal machine in a bandgap environment: non-Markovian features and anti-Zeno advantage

A minimal model of a quantum thermal machine is analyzed, where a driven two level working medium (WM) is embedded in an environment (reservoir) whose spectrum possesses bandgaps. The transition frequency of the WM is periodically modulated so as to be in alternating spectral overlap with hot or cold reservoirs whose spectra are separated by a bandgap. Approximate and exact treatments supported by analytical considerations yield a complete characterization of this thermal machine in the deep quantum domain. For slow to moderate modulation, the spectral response of the reservoirs is close to equilibrium, exhibiting sideband (Floquet) resonances in the heat currents and power output. In contrast, for faster modulation, strong-coupling and non-Markovian features give rise to correlations between the WM and the reservoirs and between the two reservoirs. Power boost of strictly quantum origin ('quantum advantage') is then found for both continuous and segmental fast modulation that leads to the anti-Zeno effect of enhanced spectral reservoir response. Such features cannot be captured by standard Markovian treatments.

Automated summary

This study analyzes a minimal model of a quantum thermal machine, in which a driven two-level working medium is embedded in an environment with a spectrum possessing bandgaps. By using approximate and exact treatments, the researchers characterize this thermal machine in the deep quantum domain. They find that the spectral response and power output of the machine exhibit different features for different modulation rates, with fast modulation leading to power boost of strictly quantum origin and enhanced spectral reservoir response.