Title :
Theoretical and experimental study of radiation pressure-induced mechanical oscillations (parametric instability) in optical microcavities
Author :
Rokhsari, H. ; Kippenberg, T.J. ; Carmon, T. ; Vahala, K.J.
Author_Institution :
Appl. Phys. Dept., California Inst. of Technol., Pasadena, CA, USA
Abstract :
Radiation pressure can couple the mechanical modes of an optical cavity structure to its optical modes, leading to parametric oscillation instability. This regime is characterized by regenerative oscillation of the mechanical cavity eigenmodes. Here, we present the first observation of this effect with a detailed theoretical and experimental analysis of these oscillations in ultra-high-Q microtoroids. Embodied within a microscale, chip-based device, this mechanism can benefit both research into macroscale quantum mechanical phenomena and improve the understanding of the mechanism within the context of laser interferometer gravitational-wave observatory (LIGO). It also suggests that new technologies are possible that will leverage the phenomenon within photonics.
Keywords :
Q-factor; cavity resonators; eigenvalues and eigenfunctions; light interferometry; micro-optics; microcavities; optical resonators; quantum optics; radiation pressure; chip-based device; laser interferometer gravitational-wave observatory; macroscale quantum mechanical phenomena; mechanical cavity eigenmodes; mechanical modes; mechanical oscillations; optical cavity structure; optical microcavities; optical modes; parametric instability; parametric oscillation; radiation pressure; regenerative oscillation; ultrahigh-Q microtoroids; Frequency; Laser theory; Microcavities; Nonlinear optics; Optical coupling; Optical interferometry; Optical modulation; Optical pumping; Optical sensors; Resonance; Optical microcavities; optomechanical; parametric instability; photonic clock; radiation pressure;
Journal_Title :
Selected Topics in Quantum Electronics, IEEE Journal of
DOI :
10.1109/JSTQE.2005.862890
