Experimental realization of a quantum heat engine based on dissipation-engineered superconducting circuits

• URL: http://arxiv.org/abs/2502.20143v1
• Date: Thu, 27 Feb 2025 14:34:29 GMT
• Title: Experimental realization of a quantum heat engine based on dissipation-engineered superconducting circuits
• Authors: Tuomas Uusnäkki, Timm Mörstedt, Wallace Teixeira, Miika Rasola, Mikko Möttönen,
• Abstract summary: We experimentally demonstrate a quantum heat engine based on superconducting circuits.<n>We implement a quantum Otto cycle by a tailored drive on the QCR to sequentially induce cooling and heating.<n>We measure positive output powers and efficiencies that agree with our simulations of the quantum evolution.
• Score: 0.0
• License: http://creativecommons.org/licenses/by-sa/4.0/
• Abstract: Quantum heat engines (QHEs) have attracted long-standing scientific interest, especially inspired by considerations of the interplay between heat and work with the quantization of energy levels, quantum superposition, and entanglement. Operating QHEs calls for effective control of the thermal reservoirs and the eigenenergies of the quantum working medium of the engine. Although superconducting circuits enable accurate engineering of controlled quantum systems, beneficial in quantum computing, this framework has not yet been employed to experimentally realize a cyclic QHE. Here, we experimentally demonstrate a quantum heat engine based on superconducting circuits, using a single-junction quantum-circuit refrigerator (QCR) as a two-way tunable heat reservoir coupled to a flux-tunable transmon qubit acting as the working medium of the engine. We implement a quantum Otto cycle by a tailored drive on the QCR to sequentially induce cooling and heating, interleaved with flux ramps that control the qubit frequency. Utilizing single-shot qubit readout, we monitor the evolution of the qubit state during several cycles of the heat engine and measure positive output powers and efficiencies that agree with our simulations of the quantum evolution. Our results verify theoretical models on the thermodynamics of quantum heat engines and advance the control of dissipation-engineered thermal environments. These proof-of-concept results pave the way for explorations on possible advantages of QHEs with respect to classical heat engines.

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