Optomechanical measurement of a millimeter-sized mechanical oscillator approaching the quantum ground state

J. T. Santos; Jian Li; J. Ilves; C. F. Ockeloen-Korppi; M. Sillanpaa

doi:10.1088/1367-2630/aa83a5

Optomechanical measurement of a millimeter-sized mechanical oscillator approaching the quantum ground state

J. T. Santos, Jian Li, J. Ilves, C. F. Ockeloen-Korppi, M. Sillanpaa^*

^*Tämän työn vastaava kirjoittaja

Tutkimustuotos: Lehtiartikkeli › Article › Scientific › vertaisarvioitu

16 Sitaatiot (Scopus)

281 Lataukset (Pure)

Abstrakti

Cavity optomechanics is a tool to study the interaction between light and micromechanical motion. Here we observe optomechanical physics in a truly macroscopic oscillator close to the quantum ground state. As the mechanical system, we use a mm-sized piezoelectric quartz disk oscillator. Its motion is coupled to a charge qubit which translates the piezo-induced charge into an effective radiation-pressure interaction between the disk and a microwave cavity. We measure the thermal motion of the lowest mechanical shear mode at 7 MHz down to 30 mK, corresponding to roughly 10 2 quanta in a 20 mg oscillator. We estimate that with realistic parameters, it is possible to utilize the back-action cooling by the qubit in order to control macroscopic motion by a single Cooper pair. The work opens up opportunities for macroscopic quantum experiments.

Alkuperäiskieli	Englanti
Artikkeli	103014
Sivut	1-11
Sivumäärä	11
Julkaisu	New Journal of Physics
Vuosikerta	19
DOI - pysyväislinkit	https://doi.org/10.1088/1367-2630/aa83a5
Tila	Julkaistu - 12 lokak. 2017
OKM-julkaisutyyppi	A1 Alkuperäisartikkeli tieteellisessä aikakauslehdessä

Pääsy asiakirjaan

10.1088/1367-2630/aa83a5

Santos_2017_New_J._Phys._19_103014Final published version, 1,04 MBLisenssi: CC BY

HOT: Hybrid Optomechanical Technologies
Sillanpää, M. (Vastuullinen tutkija)
01/01/2017 → 30/06/2021
Projekti: EU: Framework programmes funding
Matalien lämpötilojen kvantti-ilmiöiden ja komponenttien huippuyksikkö
Sillanpää, M. (Vastuullinen tutkija)
01/01/2015 → 31/12/2017
Projekti: Academy of Finland: Other research funding
CAVITYQPD: Cavity quantum phonon dynamics
Välimaa, A. (Projektin jäsen), Ockeloen-Korppi, C. (Projektin jäsen), Santos, J. T. (Projektin jäsen), Damskägg, E. (Projektin jäsen), Sillanpää, M. (Vastuullinen tutkija), Rissanen, I. (Projektin jäsen), Kervinen, M. (Projektin jäsen), Brandt, M. (Projektin jäsen), Sulkko, J. (Projektin jäsen), Pirkkalainen, J.-M. (Projektin jäsen), Zhou, J. (Projektin jäsen), Mahato, S. (Projektin jäsen), Mercier de Lepinay, L. (Projektin jäsen), Mishra, H. (Projektin jäsen), Wang, C. (Projektin jäsen), Tong, F. (Projektin jäsen) & Crump, W. (Projektin jäsen)
20/11/2014 → 31/12/2020
Projekti: EU: ERC grants

OtaNano – Kylmälaboratorio
Savin, A. (Manager) & Rissanen, A. (Other)
OtaNano
Laitteistot/tilat: Facility
OtaNano Nanofab
Repo, P. (Manager) & Rissanen, A. (Other)
OtaNano
Laitteistot/tilat: Facility

Siteeraa tätä

@article{c6535c5b1dd54e5fb0aa483d31348e5c,

title = "Optomechanical measurement of a millimeter-sized mechanical oscillator approaching the quantum ground state",

abstract = "Cavity optomechanics is a tool to study the interaction between light and micromechanical motion. Here we observe optomechanical physics in a truly macroscopic oscillator close to the quantum ground state. As the mechanical system, we use a mm-sized piezoelectric quartz disk oscillator. Its motion is coupled to a charge qubit which translates the piezo-induced charge into an effective radiation-pressure interaction between the disk and a microwave cavity. We measure the thermal motion of the lowest mechanical shear mode at 7 MHz down to 30 mK, corresponding to roughly 10 2 quanta in a 20 mg oscillator. We estimate that with realistic parameters, it is possible to utilize the back-action cooling by the qubit in order to control macroscopic motion by a single Cooper pair. The work opens up opportunities for macroscopic quantum experiments.",

keywords = "optomechanics, superconducting qubits, mechanical oscillators, MICROMECHANICAL RESONATOR, CAVITY OPTOMECHANICS, RADIATION-PRESSURE, ARTIFICIAL ATOM, MOTION, CIRCUIT, ELECTRODYNAMICS, MICROMIRROR, ELECTRODES, SYSTEM",

author = "Santos, {J. T.} and Jian Li and J. Ilves and Ockeloen-Korppi, {C. F.} and M. Sillanpaa",

note = "| openaire: EC/H2020/732894/EU//HOT",

year = "2017",

month = oct,

day = "12",

doi = "10.1088/1367-2630/aa83a5",

language = "English",

volume = "19",

pages = "1--11",

journal = "New Journal of Physics",

issn = "1367-2630",

publisher = "Institute of Physics",

}

TY - JOUR

T1 - Optomechanical measurement of a millimeter-sized mechanical oscillator approaching the quantum ground state

AU - Santos, J. T.

AU - Li, Jian

AU - Ilves, J.

AU - Ockeloen-Korppi, C. F.

AU - Sillanpaa, M.

N1 - | openaire: EC/H2020/732894/EU//HOT

PY - 2017/10/12

Y1 - 2017/10/12

N2 - Cavity optomechanics is a tool to study the interaction between light and micromechanical motion. Here we observe optomechanical physics in a truly macroscopic oscillator close to the quantum ground state. As the mechanical system, we use a mm-sized piezoelectric quartz disk oscillator. Its motion is coupled to a charge qubit which translates the piezo-induced charge into an effective radiation-pressure interaction between the disk and a microwave cavity. We measure the thermal motion of the lowest mechanical shear mode at 7 MHz down to 30 mK, corresponding to roughly 10 2 quanta in a 20 mg oscillator. We estimate that with realistic parameters, it is possible to utilize the back-action cooling by the qubit in order to control macroscopic motion by a single Cooper pair. The work opens up opportunities for macroscopic quantum experiments.

AB - Cavity optomechanics is a tool to study the interaction between light and micromechanical motion. Here we observe optomechanical physics in a truly macroscopic oscillator close to the quantum ground state. As the mechanical system, we use a mm-sized piezoelectric quartz disk oscillator. Its motion is coupled to a charge qubit which translates the piezo-induced charge into an effective radiation-pressure interaction between the disk and a microwave cavity. We measure the thermal motion of the lowest mechanical shear mode at 7 MHz down to 30 mK, corresponding to roughly 10 2 quanta in a 20 mg oscillator. We estimate that with realistic parameters, it is possible to utilize the back-action cooling by the qubit in order to control macroscopic motion by a single Cooper pair. The work opens up opportunities for macroscopic quantum experiments.

KW - optomechanics

KW - superconducting qubits

KW - mechanical oscillators

KW - MICROMECHANICAL RESONATOR

KW - CAVITY OPTOMECHANICS

KW - RADIATION-PRESSURE

KW - ARTIFICIAL ATOM

KW - MOTION

KW - CIRCUIT

KW - ELECTRODYNAMICS

KW - MICROMIRROR

KW - ELECTRODES

KW - SYSTEM

U2 - 10.1088/1367-2630/aa83a5

DO - 10.1088/1367-2630/aa83a5

M3 - Article

SN - 1367-2630

VL - 19

SP - 1

EP - 11

JO - New Journal of Physics

JF - New Journal of Physics

M1 - 103014

ER -

Optomechanical measurement of a millimeter-sized mechanical oscillator approaching the quantum ground state

Abstrakti

Pääsy asiakirjaan

Sormenjälki

Projektit

HOT: Hybrid Optomechanical Technologies

Matalien lämpötilojen kvantti-ilmiöiden ja komponenttien huippuyksikkö

CAVITYQPD: Cavity quantum phonon dynamics

Laitteet

OtaNano – Kylmälaboratorio

OtaNano Nanofab

Siteeraa tätä