Strong-coupling quantum thermodynamics using a superconducting flux qubit

TL;DR

This paper demonstrates experimental evidence of strong coupling heat transport in a superconducting flux qubit system, revealing hybridized states and enabling control of heat flow, advancing quantum thermodynamics research.

Contribution

It provides the first experimental demonstration of strong coupling effects in heat transport using a superconducting flux qubit, with theoretical support and potential for quantum heat engine development.

Findings

Observation of hybridized qubit-cavity states affecting heat transport

Achieved near 100% on-off heat current switching via magnetic flux

Exceeding previous experiments in heat transport power levels

Abstract

Thermodynamics in quantum circuits aims to find improved functionalities of thermal machines, highlight fundamental phenomena peculiar to quantum nature in thermodynamics, and point out limitations in quantum information processing due to coupling of the system to its environment. An important aspect to achieve some of these goals is the regime of strong coupling that has remained until now a domain of theoretical works only. Our aim is to demonstrate strong coupling features in heat transport using a superconducting flux qubit, which is capable of reaching strong to deep-ultra strong coupling regimes, as shown in previous studies. Here, we show experimental evidence of strong coupling by observing a hybridized state of the qubit with two cavities coupled to it, leading to a triplet-like thermal transport via this combined system around the minimum energy of the qubit, at power levels of tens of femtowatts, exceeding by an order of magnitude those in earlier experiments. We also demonstrate close to 100% on-off switching ratio of heat current mediated by photons by applying magnetic flux to the qubit. Our experiment opens a way towards testing debated questions in strong coupling thermodynamics such as what heat in this regime is. We also present a theoretical model that aligns with our experimental findings and explains the mechanism behind heat transport in our device. Furthermore, our experiment opens new possibilities for quantum thermodynamics, aiming to realize true quantum heat engines and refrigerators with enhanced power and efficiency, by leveraging ultra-strong coupling between the system and its environment in future experiments.