| Project Detail |
Harnessing heat exchanges from quantum mechanics
The laws of thermodynamics frame our understanding of engines and heat exchanges, but discoveries in quantum mechanics show that they may need an update. The EU-funded ESQuAT project seeks to shed light on this by creating a new test circuit for experiments with quantum thermal machines. Researchers will develop an engineered physical bath that can be populated with any spectral distribution. This can then be connected to quantum thermal machines and heat flows can be spectrally tracked. The project will also test three types of refrigerators that cool based on the quantum principles of coherence, measurement backaction and collective effects. The ultimate objective is to make more powerful engines, faster-charging batteries and devices that reduce energy waste.
The technology advances of the last decades are forcing us to re-think laws and concepts of thermodynamics. An intense theoretical effort is underway to understand the role of quantum mechanical ingredients in thermodynamic processes. This effort might ultimately lead to more powerful engines, less energy waste, faster-charging batteries. However, despite pioneering experimental work, progress is hindered by the lack of a comprehensive experimental testbed for quantum thermal machines.
In this project I aim to provide the most ambitious and systematic experimental search for quantum advantages in thermodynamics thus far, based on a circuit quantum electrodynamics architecture.
I will first complement the toolkit of circuit quantum electrodynamics with a novel arrangement, which I term the engineered physical bath. This bath has a broadband, Ohmic spectral density. It can be populated with any spectral distribution and coupled to quantum thermal machines with arbitrary strengths. Finally, heat flows between the bath and the machine can be detected deep in the quantum regime and in a spectrally resolved way. Based on this augmented architecture, I will implement three types of novel quantum refrigerators. I devised each refrigerator to pinpoint the utilization of a specific quantum resource: quantum coherence, measurement backaction, and collective effects. I will measure the cooling power of the refrigerators while in situ exploring an unprecedently large space of parameters and connect my results to the most recent theoretical frameworks.
From this investigation, I expect two kinds of scientific breakthroughs: (i) observation of features that are unambiguously nonclassical in thermodynamic observables, and (ii) determination of advantages enjoyed by quantum thermal machines when fairly compared to their classical counterparts. Broadly, this project will deepen our understanding of quantum thermodynamics while establishing a new standard for experiments in the field. |
