Tunable photonic heat transport in a quantum heat valve

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Tunable photonic heat transport in a quantum heat valve. / Ronzani, Alberto; Karimi, Bayan; Senior, Jorden; Chang, Yu Cheng; Peltonen, Joonas T.; Chen, Chii Dong; Pekola, Jukka P.

In: Nature Physics, Vol. 14, 2018, p. 991–995.

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@article{4ba1a1381b4643469aa69b8cc01b0d74,
title = "Tunable photonic heat transport in a quantum heat valve",
abstract = "Quantum thermodynamics is emerging both as a topic of fundamental research and as a means to understand and potentially improve the performance of quantum devices1–10. A prominent platform for achieving the necessary manipulation of quantum states is superconducting circuit quantum electrodynamics (QED)11. In this platform, thermalization of a quantum system12–15 can be achieved by interfacing the circuit QED subsystem with a thermal reservoir of appropriate Hilbert dimensionality. Here we study heat transport through an assembly consisting of a superconducting qubit16 capacitively coupled between two nominally identical coplanar waveguide resonators, each equipped with a heat reservoir in the form of a normal-metal mesoscopic resistor termination. We report the observation of tunable photonic heat transport through the resonator–qubit–resonator assembly, showing that the reservoir-to-reservoir heat flux depends on the interplay between the qubit–resonator and the resonator–reservoir couplings, yielding qualitatively dissimilar results in different coupling regimes. Our quantum heat valve is relevant for the realization of quantum heat engines17 and refrigerators, which can be obtained, for example, by exploiting the time-domain dynamics and coherence of driven superconducting qubits18,19. This effort would ultimately bridge the gap between the fields of quantum information and thermodynamics of mesoscopic systems.",
author = "Alberto Ronzani and Bayan Karimi and Jorden Senior and Chang, {Yu Cheng} and Peltonen, {Joonas T.} and Chen, {Chii Dong} and Pekola, {Jukka P.}",
note = "| openaire: EC/H2020/742559/EU//SQH | openaire: EC/H2020/766025/EU//QuESTech",
year = "2018",
doi = "10.1038/s41567-018-0199-4",
language = "English",
volume = "14",
pages = "991–995",
journal = "Nature Physics",
issn = "1745-2473",
publisher = "Nature Publishing Group",

}

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TY - JOUR

T1 - Tunable photonic heat transport in a quantum heat valve

AU - Ronzani, Alberto

AU - Karimi, Bayan

AU - Senior, Jorden

AU - Chang, Yu Cheng

AU - Peltonen, Joonas T.

AU - Chen, Chii Dong

AU - Pekola, Jukka P.

N1 - | openaire: EC/H2020/742559/EU//SQH | openaire: EC/H2020/766025/EU//QuESTech

PY - 2018

Y1 - 2018

N2 - Quantum thermodynamics is emerging both as a topic of fundamental research and as a means to understand and potentially improve the performance of quantum devices1–10. A prominent platform for achieving the necessary manipulation of quantum states is superconducting circuit quantum electrodynamics (QED)11. In this platform, thermalization of a quantum system12–15 can be achieved by interfacing the circuit QED subsystem with a thermal reservoir of appropriate Hilbert dimensionality. Here we study heat transport through an assembly consisting of a superconducting qubit16 capacitively coupled between two nominally identical coplanar waveguide resonators, each equipped with a heat reservoir in the form of a normal-metal mesoscopic resistor termination. We report the observation of tunable photonic heat transport through the resonator–qubit–resonator assembly, showing that the reservoir-to-reservoir heat flux depends on the interplay between the qubit–resonator and the resonator–reservoir couplings, yielding qualitatively dissimilar results in different coupling regimes. Our quantum heat valve is relevant for the realization of quantum heat engines17 and refrigerators, which can be obtained, for example, by exploiting the time-domain dynamics and coherence of driven superconducting qubits18,19. This effort would ultimately bridge the gap between the fields of quantum information and thermodynamics of mesoscopic systems.

AB - Quantum thermodynamics is emerging both as a topic of fundamental research and as a means to understand and potentially improve the performance of quantum devices1–10. A prominent platform for achieving the necessary manipulation of quantum states is superconducting circuit quantum electrodynamics (QED)11. In this platform, thermalization of a quantum system12–15 can be achieved by interfacing the circuit QED subsystem with a thermal reservoir of appropriate Hilbert dimensionality. Here we study heat transport through an assembly consisting of a superconducting qubit16 capacitively coupled between two nominally identical coplanar waveguide resonators, each equipped with a heat reservoir in the form of a normal-metal mesoscopic resistor termination. We report the observation of tunable photonic heat transport through the resonator–qubit–resonator assembly, showing that the reservoir-to-reservoir heat flux depends on the interplay between the qubit–resonator and the resonator–reservoir couplings, yielding qualitatively dissimilar results in different coupling regimes. Our quantum heat valve is relevant for the realization of quantum heat engines17 and refrigerators, which can be obtained, for example, by exploiting the time-domain dynamics and coherence of driven superconducting qubits18,19. This effort would ultimately bridge the gap between the fields of quantum information and thermodynamics of mesoscopic systems.

UR - http://www.scopus.com/inward/record.url?scp=85049654705&partnerID=8YFLogxK

U2 - 10.1038/s41567-018-0199-4

DO - 10.1038/s41567-018-0199-4

M3 - Article

VL - 14

SP - 991

EP - 995

JO - Nature Physics

JF - Nature Physics

SN - 1745-2473

ER -

ID: 26620502