Radiation pressure backaction on a hexagonal boron nitride nanomechanical resonator

TL;DR

This paper demonstrates radiation pressure backaction on a hexagonal boron nitride nanomechanical resonator at telecom wavelengths, enabling optomechanical control for hybrid quantum devices.

Contribution

First observation of radiation pressure backaction on hBN resonators, coupling thermomechanical motion to an optical cavity at telecom wavelengths.

Findings

Resolved optical spring effect and optomechanical damping.

Achieved single photon coupling strength of 1200 Hz.

Paves the way for light-tuned mechanical properties of hBN.

Abstract

Hexagonal boron nitride (hBN) is a van der Waals material with excellent mechanical properties hosting quantum emitters and optically active spin defects, several of them being sensitive to strain. Establishing optomechanical control of hBN will enable hybrid quantum devices that combine the spin degree of freedom with the cavity optomechanical toolbox. In this letter, we report the first observation of radiation pressure backaction at telecom wavelengths with a hBN drum-head mechanical resonator. The thermomechanical motion of the resonator is coupled to the optical mode of a high finesse fiber-based Fabry-P\'erot microcavity in a membrane-in-the-middle configuration. We are able to resolve the optical spring effect and optomechanical damping with a single photon coupling strength of $g_0/2\pi = 1200$ Hz. Our results pave the way for tailoring the mechanical properties of hBN resonators with light.