Temporal behavior of radiation-pressure-induced vibrations of an optical microcavity phonon mode

Tal Carmon; Hossein Rokhsari; Lan Yang; Tobias J. Kippenberg; Kerry J. Vahala

doi:10.1103/PhysRevLett.94.223902

Temporal behavior of radiation-pressure-induced vibrations of an optical microcavity phonon mode

Tal Carmon, Hossein Rokhsari, Lan Yang, Tobias J. Kippenberg, Kerry J. Vahala

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

517 Scopus citations

Abstract

We analyze experimentally and theoretically mechanical oscillation within an optical cavity stimulated by the pressure of circulating optical radiation. The resulting radio frequency cavity vibrations (phonon mode) cause modulation of the incident, continuous-wave (cw) input pump beam. Furthermore, with increasing cw pump power, an evolution from sinusoidal modulation to random oscillations is observed in the pump power coupled from the resonator. The temporal evolution with pump power is studied, and agreement was found with theory. In addition to applications in quantum optomechanics, the present work suggests that radiation-pressure-induced effects can establish a practical limit for the miniaturization of optical silica microcavities.

Original language	English
Article number	223902
Journal	Physical Review Letters
Volume	94
Issue number	22
DOIs	https://doi.org/10.1103/PhysRevLett.94.223902
State	Published - Jun 10 2005

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10.1103/PhysRevLett.94.223902

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abstract = "We analyze experimentally and theoretically mechanical oscillation within an optical cavity stimulated by the pressure of circulating optical radiation. The resulting radio frequency cavity vibrations (phonon mode) cause modulation of the incident, continuous-wave (cw) input pump beam. Furthermore, with increasing cw pump power, an evolution from sinusoidal modulation to random oscillations is observed in the pump power coupled from the resonator. The temporal evolution with pump power is studied, and agreement was found with theory. In addition to applications in quantum optomechanics, the present work suggests that radiation-pressure-induced effects can establish a practical limit for the miniaturization of optical silica microcavities.",

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AU - Rokhsari, Hossein

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AU - Kippenberg, Tobias J.

AU - Vahala, Kerry J.

PY - 2005/6/10

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AB - We analyze experimentally and theoretically mechanical oscillation within an optical cavity stimulated by the pressure of circulating optical radiation. The resulting radio frequency cavity vibrations (phonon mode) cause modulation of the incident, continuous-wave (cw) input pump beam. Furthermore, with increasing cw pump power, an evolution from sinusoidal modulation to random oscillations is observed in the pump power coupled from the resonator. The temporal evolution with pump power is studied, and agreement was found with theory. In addition to applications in quantum optomechanics, the present work suggests that radiation-pressure-induced effects can establish a practical limit for the miniaturization of optical silica microcavities.

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JO - Physical Review Letters

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Temporal behavior of radiation-pressure-induced vibrations of an optical microcavity phonon mode

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