Non-Gaussian Mechanical Motion via Single and Multiphonon Subtraction from a Thermal State

G. Enzian; L. Freisem; J. J. Price; A. O. Svela; J. Clarke; B. Shajilal; J. Janousek; B. C. Buchler; P. K. Lam; M. R. Vanner

doi:10.1103/PhysRevLett.127.243601

Non-Gaussian Mechanical Motion via Single and Multiphonon Subtraction from a Thermal State

G. Enzian, L. Freisem, J. J. Price, A. O. Svela, J. Clarke, B. Shajilal, J. Janousek, B. C. Buchler, P. K. Lam, M. R. Vanner^*

^*Corresponding author for this work

Quantum Optics and Photonics

Research output: Contribution to journal › Letter › peer-review

29 Citations (Scopus)

13 Downloads (Pure)

Abstract

Quantum optical measurement techniques offer a rich avenue for quantum control of mechanical oscillators via cavity optomechanics. In particular, a powerful yet little explored combination utilizes optical measurements to perform heralded non-Gaussian mechanical state preparation followed by tomography to determine the mechanical phase-space distribution. Here, we experimentally perform heralded single-phonon and multiphonon subtraction via photon counting to a laser-cooled mechanical thermal state with a Brillouin optomechanical system at room temperature and use optical heterodyne detection to measure the s-parametrized Wigner distribution of the non-Gaussian mechanical states generated. The techniques developed here advance the state of the art for optics-based tomography of mechanical states and will be useful for a broad range of applied and fundamental studies that utilize mechanical quantum-state engineering and tomography.

Original language	English
Article number	243601
Journal	Physical Review Letters
Volume	127
Issue number	24
Number of pages	6
ISSN	0031-9007
DOIs	https://doi.org/10.1103/PhysRevLett.127.243601
Publication status	Published - 8 Dec 2021

Keywords

QUANTUM STATE
RECONSTRUCTION
RESONATOR
PHOTONS
QUBIT

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10.1103/PhysRevLett.127.243601

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Cite this

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title = "Non-Gaussian Mechanical Motion via Single and Multiphonon Subtraction from a Thermal State",

abstract = "Quantum optical measurement techniques offer a rich avenue for quantum control of mechanical oscillators via cavity optomechanics. In particular, a powerful yet little explored combination utilizes optical measurements to perform heralded non-Gaussian mechanical state preparation followed by tomography to determine the mechanical phase-space distribution. Here, we experimentally perform heralded single-phonon and multiphonon subtraction via photon counting to a laser-cooled mechanical thermal state with a Brillouin optomechanical system at room temperature and use optical heterodyne detection to measure the s-parametrized Wigner distribution of the non-Gaussian mechanical states generated. The techniques developed here advance the state of the art for optics-based tomography of mechanical states and will be useful for a broad range of applied and fundamental studies that utilize mechanical quantum-state engineering and tomography.",

keywords = "QUANTUM STATE, RECONSTRUCTION, RESONATOR, PHOTONS, QUBIT",

author = "G. Enzian and L. Freisem and Price, {J. J.} and Svela, {A. O.} and J. Clarke and B. Shajilal and J. Janousek and Buchler, {B. C.} and Lam, {P. K.} and Vanner, {M. R.}",

year = "2021",

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doi = "10.1103/PhysRevLett.127.243601",

language = "English",

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journal = "Physical Review Letters",

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T1 - Non-Gaussian Mechanical Motion via Single and Multiphonon Subtraction from a Thermal State

AU - Enzian, G.

AU - Freisem, L.

AU - Price, J. J.

AU - Svela, A. O.

AU - Clarke, J.

AU - Shajilal, B.

AU - Janousek, J.

AU - Buchler, B. C.

AU - Lam, P. K.

AU - Vanner, M. R.

PY - 2021/12/8

Y1 - 2021/12/8

N2 - Quantum optical measurement techniques offer a rich avenue for quantum control of mechanical oscillators via cavity optomechanics. In particular, a powerful yet little explored combination utilizes optical measurements to perform heralded non-Gaussian mechanical state preparation followed by tomography to determine the mechanical phase-space distribution. Here, we experimentally perform heralded single-phonon and multiphonon subtraction via photon counting to a laser-cooled mechanical thermal state with a Brillouin optomechanical system at room temperature and use optical heterodyne detection to measure the s-parametrized Wigner distribution of the non-Gaussian mechanical states generated. The techniques developed here advance the state of the art for optics-based tomography of mechanical states and will be useful for a broad range of applied and fundamental studies that utilize mechanical quantum-state engineering and tomography.

AB - Quantum optical measurement techniques offer a rich avenue for quantum control of mechanical oscillators via cavity optomechanics. In particular, a powerful yet little explored combination utilizes optical measurements to perform heralded non-Gaussian mechanical state preparation followed by tomography to determine the mechanical phase-space distribution. Here, we experimentally perform heralded single-phonon and multiphonon subtraction via photon counting to a laser-cooled mechanical thermal state with a Brillouin optomechanical system at room temperature and use optical heterodyne detection to measure the s-parametrized Wigner distribution of the non-Gaussian mechanical states generated. The techniques developed here advance the state of the art for optics-based tomography of mechanical states and will be useful for a broad range of applied and fundamental studies that utilize mechanical quantum-state engineering and tomography.

KW - QUANTUM STATE

KW - RECONSTRUCTION

KW - RESONATOR

KW - PHOTONS

KW - QUBIT

U2 - 10.1103/PhysRevLett.127.243601

DO - 10.1103/PhysRevLett.127.243601

M3 - Letter

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JO - Physical Review Letters

JF - Physical Review Letters

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