High frequency torsional motion transduction using optomechanical coupled oscillators

TL;DR

This paper presents a novel optomechanical system that converts high-frequency torsional motion of a nanodisk into vibrations of a photonic crystal cavity, enabling highly sensitive torque measurements without compromising optical properties.

Contribution

The authors demonstrate a system that measures high-frequency torsional motion via optomechanical coupling, overcoming limitations of traditional cavity optomechanical sensors.

Findings

Achieved torque sensitivity of 5.1×10⁻²¹ to 1.2×10⁻¹⁹ Nm/√Hz.

Measured torsional resonances in the 5-800 MHz range.

System allows integration of magnetic nanostructures without affecting optical properties.

Abstract

Using light to measure an object's motion is central to operating mechanical sensors that probe forces and fields. Cavity optomechanical systems embed mechanical resonators inside optical resonators. This enhances the sensitivity of optomechanical measurements, but only if the mechanical resonator does not spoil the properties of the optical cavity. For example, cavity optomechanical detection of resonators made from optically absorbing materials, or whose geometry does not possess suitable spatial symmetry, is challenging. Here we demonstrate a system that overcomes challenges in measuring high-frequency twisting motion of a nanodisk by converting them to vibrations of a photonic crystal cavity. Optomechanical readout of the cavity then enables measurement of the nanodisk's torsional resonances with sensitivity $5.1\times 10^{-21}-1.2\times 10^{-19}\,\text{Nm}/\sqrt{\text{Hz}}$ for a mechanical frequency range of 5--800 MHz. The nanodisk can be outfitted with magnetic nanostructures or metasurfaces without affecting the optical properties of the cavity, making the system suitable for torque magnetometry and structured light sensing.