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Abstract:

Driven quantum thermal machines, such as heat engines and refrigerators, are quantum devices that allow us to control the conversion between heat and work at the micro scale through time-dependent controls. Their performance is mainly characterized by their power, efficiency, and power fluctuations. However, optimizing such quantities is challenging: in finite-time, the state can be driven far from equilibrium, and the space of all possible time-dependent cycles is exponentially large. While general results have been found in the slow [1] and fast [2] driving regime – general finite-time optimization schemes are currently lacking.

We introduce a model-free framework based on Reinforcement Learning to discover optimal cycles for quantum thermal machines [3]. Our method makes no assumptions on the structure, shape or speed of the cycle. We employ our method to maximize trade-offs between high power, high efficiency, and low power fluctuations in simple models of quantum heat engines and refrigerators [4-5], including a refrigerator based on a superconducting qubit [6]. We find cycles that outperform previous proposals made in literature, such as Otto cycles, and we show that such cycles mitigate the detrimental effect of generation of coherence, also known as "quantum friction". 

References:

[1] P. Abiuso and M. Perarnau-Llobet, Phys. Rev. Lett. 124, 110606 (2020).

[2] V. Cavina, P.A. Erdman, P. Abiuso, L. Tolomeo, and V. Giovannetti, Phys. Rev. A 104, 032226 (2021). 

[3] P.A. Erdman and F. Noé, NPJ Quantum Inf. 8, 1 (2022).

[4] P.A. Erdman, A. Rolandi, P. Abiuso, M. Perarnau-Llobet, and F. Noé, arXiv:2207.13104 (2022).

[5] P.A. Erdman and F. Noé, arXiv:2204.04785 (2022).

[6] B. Karimi and J. P. Pekola, Phys. Rev. B 94, 184503 (2016).