Ground-state cooling of a mechanical oscillator by a noisy environment

Cheng Wang; Louise Banniard; Kjetil Børkje; Francesco Massel; Laure Mercier de Lépinay; Mika A. Sillanpää

doi:10.1038/s41467-024-51645-7

Ground-state cooling of a mechanical oscillator by a noisy environment

Cheng Wang, Louise Banniard, Kjetil Børkje, Francesco Massel, Laure Mercier de Lépinay, Mika A. Sillanpää^*

^*Tämän työn vastaava kirjoittaja

University of South-Eastern Norway

Tutkimustuotos: Lehtiartikkeli › Article › Scientific › vertaisarvioitu

1 Sitaatiot (Scopus)

40 Lataukset (Pure)

Abstrakti

Dissipation and the accompanying fluctuations are often seen as detrimental for quantum systems since they are associated with fast relaxation and loss of phase coherence. However, it has been proposed that a pure state can be prepared if external noise induces suitable downwards transitions, while exciting transitions are blocked. We demonstrate such a refrigeration mechanism in a cavity optomechanical system, where we prepare a mechanical oscillator in its ground state by injecting strong electromagnetic noise at frequencies around the red mechanical sideband of the cavity. The optimum cooling is reached with a noise bandwidth smaller than but on the order of the cavity decay rate. At higher bandwidths, cooling is less efficient as suitable transitions are not effectively activated. In the opposite regime where the noise bandwidth becomes comparable to the mechanical damping rate, damping follows the noise amplitude adiabatically, and the cooling is also suppressed.

Alkuperäiskieli	Englanti
Artikkeli	7395
Sivut	1-12
Sivumäärä	12
Julkaisu	Nature Communications
Vuosikerta	15
Numero	1
DOI - pysyväislinkit	https://doi.org/10.1038/s41467-024-51645-7
Tila	Julkaistu - jouluk. 2024
OKM-julkaisutyyppi	A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä

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10.1038/s41467-024-51645-7Lisenssi: CC BY-NC-ND

Ground-state cooling of a mechanical oscillator by a noisy environmentFinal published version, 884 KBLisenssi: CC BY-NC-ND

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MQSens: Quantum sensing with nonclassical mechanical resonators
Sillanpää, M. (Vastuullinen tutkija) & Banniard, L. (Projektin jäsen)
01/09/2022 → 30/08/2025
Projekti: Academy of Finland: Other research funding
GUANTUM: Probing the limits of quantum mechanics and gravity with micromechanical oscillators
Sillanpää, M. (Vastuullinen tutkija), Cutting, R. (Projektin jäsen), Välimaa, A. (Projektin jäsen), Wang, C. (Projektin jäsen), Depellette, J. (Projektin jäsen), Rej, E. (Projektin jäsen), Lin, G. (Projektin jäsen) & Herbst, M. (Projektin jäsen)
01/10/2021 → 30/09/2026
Projekti: EU: ERC grants
Laure Mercier de Lepinay Postdoc: Vacuum forces between superconductors probed with microwave optomechanics
Mercier de Lepinay, L. (Vastuullinen tutkija) & Korkmazgil, P. (Projektin jäsen)
01/09/2021 → 31/08/2024
Projekti: Academy of Finland: Other research funding

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abstract = "Dissipation and the accompanying fluctuations are often seen as detrimental for quantum systems since they are associated with fast relaxation and loss of phase coherence. However, it has been proposed that a pure state can be prepared if external noise induces suitable downwards transitions, while exciting transitions are blocked. We demonstrate such a refrigeration mechanism in a cavity optomechanical system, where we prepare a mechanical oscillator in its ground state by injecting strong electromagnetic noise at frequencies around the red mechanical sideband of the cavity. The optimum cooling is reached with a noise bandwidth smaller than but on the order of the cavity decay rate. At higher bandwidths, cooling is less efficient as suitable transitions are not effectively activated. In the opposite regime where the noise bandwidth becomes comparable to the mechanical damping rate, damping follows the noise amplitude adiabatically, and the cooling is also suppressed.",

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AU - Mercier de Lépinay, Laure

AU - Sillanpää, Mika A.

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N2 - Dissipation and the accompanying fluctuations are often seen as detrimental for quantum systems since they are associated with fast relaxation and loss of phase coherence. However, it has been proposed that a pure state can be prepared if external noise induces suitable downwards transitions, while exciting transitions are blocked. We demonstrate such a refrigeration mechanism in a cavity optomechanical system, where we prepare a mechanical oscillator in its ground state by injecting strong electromagnetic noise at frequencies around the red mechanical sideband of the cavity. The optimum cooling is reached with a noise bandwidth smaller than but on the order of the cavity decay rate. At higher bandwidths, cooling is less efficient as suitable transitions are not effectively activated. In the opposite regime where the noise bandwidth becomes comparable to the mechanical damping rate, damping follows the noise amplitude adiabatically, and the cooling is also suppressed.

AB - Dissipation and the accompanying fluctuations are often seen as detrimental for quantum systems since they are associated with fast relaxation and loss of phase coherence. However, it has been proposed that a pure state can be prepared if external noise induces suitable downwards transitions, while exciting transitions are blocked. We demonstrate such a refrigeration mechanism in a cavity optomechanical system, where we prepare a mechanical oscillator in its ground state by injecting strong electromagnetic noise at frequencies around the red mechanical sideband of the cavity. The optimum cooling is reached with a noise bandwidth smaller than but on the order of the cavity decay rate. At higher bandwidths, cooling is less efficient as suitable transitions are not effectively activated. In the opposite regime where the noise bandwidth becomes comparable to the mechanical damping rate, damping follows the noise amplitude adiabatically, and the cooling is also suppressed.

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Ground-state cooling of a mechanical oscillator by a noisy environment

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Projektit

MQSens: Quantum sensing with nonclassical mechanical resonators

GUANTUM: Probing the limits of quantum mechanics and gravity with micromechanical oscillators

Laure Mercier de Lepinay Postdoc: Vacuum forces between superconductors probed with microwave optomechanics

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