A review on Aharonov-Bohm quantum machines: Thermoelectric heat engines and diodes

TL;DR

This review explores how quantum interference and magnetic fields in Aharonov-Bohm quantum devices can enhance thermoelectric energy conversion, revealing new control mechanisms and bounds on performance.

Contribution

It provides a comprehensive overview of quantum thermoelectric heat engines based on Aharonov-Bohm interferometry, highlighting design strategies and the impact of broken time-reversal symmetry.

Findings

Quantum interference enhances thermoelectric transport.

Magnetic fields can optimize power and efficiency bounds.

Broken time-reversal symmetry induces diode effects.

Abstract

The study of heat-to-work conversion has gained significant attention in recent years, highlighting the potential of nanoscale systems to achieve energy conversion in steady-state devices without any macroscopic moving parts. This review examines the theoretical frameworks governing the steady-state flows of quantum particles like electrons, photons, and phonons within various mesoscopic or nanoscale devices, such as thermoelectric heat engines in the context of quantum dot Aharonov-Bohm (AB) interferometric configurations. Quantum interference effects hold great promise for enhancing the thermoelectric transport properties of such quantum devices by allowing more precise control over energy levels and transport pathways. Driven quantum dot AB networks can maintain quantum coherence and provide precise experimental control. Unlike bulk systems, nanoscale systems like quantum dots reveal distinct quantum interference phenomena, including sharp features in transmission spectra and Fano resonances. This review highlights the distinction between optimization methods that produce boxcar functions and coherent control methods that result in complex interference patterns. It reveals that the effective design of thermoelectric heat engines requires careful tailoring of quantum interference and the magnetic field-induced effects to enhance performance. We emphasize how magnetic fields can change the bounds of power or efficiency. These machines with broken time-reversal symmetry provide insights into directional dependencies and asymmetries in quantum transport. We offer a thorough overview of past and current research on quantum thermoelectric heat engines using the AB effect and present a detailed review of three-terminal AB heat engines, where broken time-reversal symmetry can induce a coherent diode effect. We cover bounds on power and efficiency in systems with broken time-reversal symmetry.