Optical self-cooling of a membrane oscillator in a cavity optomechanical experiment at room temperature

P. Vezio; M. Bonaldi; A. Borrielli; F. Marino; B. Morana; P. M. Sarro; E. Serra; F. Marin

doi:10.1103/PhysRevA.108.063508

Optical self-cooling of a membrane oscillator in a cavity optomechanical experiment at room temperature

P. Vezio, M. Bonaldi, A. Borrielli, F. Marino, B. Morana, P. M. Sarro, E. Serra, F. Marin

Research output: Contribution to journal › Article › Scientific › peer-review

Abstract

Thermal noise is a major obstacle to observing quantum behavior in macroscopic systems. To mitigate its effect, quantum optomechanical experiments are typically performed in a cryogenic environment. However, this condition represents a considerable complication in the transition from fundamental research to quantum technology applications. It is therefore interesting to explore the possibility of achieving the quantum regime in room-temperature experiments. In this work we test the limits of sideband-cooling vibration modes of a SiN membrane in a cavity optomechanical experiment. We obtain an effective temperature of a few millikelvins, corresponding to a phononic occupation number of around 100. We show that further cooling is prevented by the excess classical noise of our laser source, and we outline the road toward the achievement of ground state cooling.

Original language	English
Article number	063508
Number of pages	10
Journal	Physical Review A
Volume	108
Issue number	6
DOIs	https://doi.org/10.1103/PhysRevA.108.063508
Publication status	Published - 2023

Funding

Research was performed within the Project QuaSeRT funded by the QuantERA ERA-NET Cofund in Quantum Technologies implemented within the European Union's Horizon 2020 program. We also acknowledge financial support from PNRR MUR Project No. PE0000023-NQSTI.

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abstract = "Thermal noise is a major obstacle to observing quantum behavior in macroscopic systems. To mitigate its effect, quantum optomechanical experiments are typically performed in a cryogenic environment. However, this condition represents a considerable complication in the transition from fundamental research to quantum technology applications. It is therefore interesting to explore the possibility of achieving the quantum regime in room-temperature experiments. In this work we test the limits of sideband-cooling vibration modes of a SiN membrane in a cavity optomechanical experiment. We obtain an effective temperature of a few millikelvins, corresponding to a phononic occupation number of around 100. We show that further cooling is prevented by the excess classical noise of our laser source, and we outline the road toward the achievement of ground state cooling.",

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AU - Morana, B.

AU - Sarro, P. M.

AU - Serra, E.

AU - Marin, F.

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AB - Thermal noise is a major obstacle to observing quantum behavior in macroscopic systems. To mitigate its effect, quantum optomechanical experiments are typically performed in a cryogenic environment. However, this condition represents a considerable complication in the transition from fundamental research to quantum technology applications. It is therefore interesting to explore the possibility of achieving the quantum regime in room-temperature experiments. In this work we test the limits of sideband-cooling vibration modes of a SiN membrane in a cavity optomechanical experiment. We obtain an effective temperature of a few millikelvins, corresponding to a phononic occupation number of around 100. We show that further cooling is prevented by the excess classical noise of our laser source, and we outline the road toward the achievement of ground state cooling.

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Optical self-cooling of a membrane oscillator in a cavity optomechanical experiment at room temperature

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