Optomechanics with one-dimensional gallium phosphide photonic crystal cavities

Abstract

Gallium phosphide offers an attractive combination of a high refractive index (n>3 for vacuum wavelengths up to 4 μm) and a wide electronic bandgap (2.26 eV), enabling optical cavities with small mode volumes and low two-photon absorption at telecommunication wavelengths. Heating due to strongly confined light fields is therefore greatly reduced. Here, we investigate the benefits of these properties for cavity optomechanics. Utilizing a recently developed fabrication scheme based on direct wafer bonding, we realize integrated one-dimensional photonic crystal cavities made of gallium phosphide with optical quality factors as high as 1.1×105. We optimize their design to couple the optical eigenmode at ≈ 200 THz via radiation pressure to a co-localized mechanical mode with a frequency of 3 GHz, yielding sideband-resolved devices. The high vacuum optomechanical coupling rate (g0=2π× 400 kHz) permits amplification of the mechanical mode into the so-called mechanical lasing regime with input power as low as ≈ 20 μW. The observation of mechanical lasing implies a multiphoton cooperativity of C>1, an important threshold for the realization of quantum state transfer protocols. Because of the reduced thermo-optic resonance shift, optomechanically induced transparency can be detected at room temperature in addition to the normally observed optomechanically induced absorption.