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Bending the rules: Quantum effects in the operation of a microscopic heat engine in diamond

Bending the rules: Quantum effects in the operation of a microscopic heat engine in diamond
Bending the rules: Quantum effects in the operation of a microscopic heat engine in diamond

A classical heat engine that extracts work from thermal sources and which does not include coherence amongst its microscopic degrees of freedom is a fundamental concept of classical thermodynamics. In contrast, the internal states of a quantum heat engine (QHE) can exist in a coherent superposition of energy levels and a question of interest for such a QHE is whether it can exhibit thermodynamic behavior fundamentally different to that allowed in a classical engine. QHEs have recently been implemented using for example trapped ions [1]. However, experiments so far have not shown any non-classical features in their thermodynamic quantities. While the efficiency of a QHE is still bound by the Carnot limit, recent theoretical predictions show that coherence can boost its power output above the classically allowed limit for an engine using the same thermal resources [2]. Moreover, the presence of coherence was predicted to result in the equivalence of different QHE types in the limit of weak driving and short cycle duration.

OSA
Becker, Jonas N.
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Klatzow, James
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Ledingham, Patrick M.
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Weinzetl, Christian
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Kaczmarek, Krzysztof T.
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Saunders, Dylan J.
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Nunn, Joshua
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Uzdin, Raam
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Walmsley, Ian A.
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Poem, Eilon
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Becker, Jonas N.
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Klatzow, James
c72d2500-7d99-4a9f-8487-b6b47dc01b5a
Ledingham, Patrick M.
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Weinzetl, Christian
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Kaczmarek, Krzysztof T.
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Saunders, Dylan J.
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Nunn, Joshua
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Uzdin, Raam
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Walmsley, Ian A.
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Poem, Eilon
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Becker, Jonas N., Klatzow, James, Ledingham, Patrick M., Weinzetl, Christian, Kaczmarek, Krzysztof T., Saunders, Dylan J., Nunn, Joshua, Uzdin, Raam, Walmsley, Ian A. and Poem, Eilon (2019) Bending the rules: Quantum effects in the operation of a microscopic heat engine in diamond. In European Quantum Electronics Conference, EQEC_2019. vol. Part F143-EQEC , OSA..

Record type: Conference or Workshop Item (Paper)

Abstract

A classical heat engine that extracts work from thermal sources and which does not include coherence amongst its microscopic degrees of freedom is a fundamental concept of classical thermodynamics. In contrast, the internal states of a quantum heat engine (QHE) can exist in a coherent superposition of energy levels and a question of interest for such a QHE is whether it can exhibit thermodynamic behavior fundamentally different to that allowed in a classical engine. QHEs have recently been implemented using for example trapped ions [1]. However, experiments so far have not shown any non-classical features in their thermodynamic quantities. While the efficiency of a QHE is still bound by the Carnot limit, recent theoretical predictions show that coherence can boost its power output above the classically allowed limit for an engine using the same thermal resources [2]. Moreover, the presence of coherence was predicted to result in the equivalence of different QHE types in the limit of weak driving and short cycle duration.

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More information

Published date: 2019
Additional Information: Publisher Copyright: © 2019 IEEE Copyright: Copyright 2020 Elsevier B.V., All rights reserved.
Venue - Dates: European Quantum Electronics Conference, EQEC_2019, , Munich, United Kingdom, 2019-06-23 - 2019-06-27

Identifiers

Local EPrints ID: 455467
URI: http://eprints.soton.ac.uk/id/eprint/455467
PURE UUID: 6bb5ed28-1dd6-467e-8eee-570bea4520f2
ORCID for Patrick M. Ledingham: ORCID iD orcid.org/0000-0002-9804-6132

Catalogue record

Date deposited: 22 Mar 2022 17:40
Last modified: 17 Mar 2024 04:03

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Contributors

Author: Jonas N. Becker
Author: James Klatzow
Author: Christian Weinzetl
Author: Krzysztof T. Kaczmarek
Author: Dylan J. Saunders
Author: Joshua Nunn
Author: Raam Uzdin
Author: Ian A. Walmsley
Author: Eilon Poem

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