Silicon-photonic optomechanical magnetometer

TL;DR

This paper presents a silicon-on-insulator optomechanical magnetometer with enhanced sensitivity, achieved through a novel fabrication process and photonic-crystal cavities, enabling chip-scale magnetic field detection at room temperature.

Contribution

Introduction of a new fabrication process for silicon-on-insulator magnetometers that improves magnetic sensitivity and integration capabilities.

Findings

Achieved magnetic field sensitivity of 800 pT/Hz^{1/2}.

Enhanced motion-to-optical signal transduction by over an order of magnitude.

Demonstrated compatibility with integrated photonics and electronics.

Abstract

Optomechanical sensors enable exquisitely sensitive force measurements, with emerging applications across quantum technologies, standards, fundamental science, and engineering. Magnetometry is among the most promising applications, where chip-scale optomechanical sensors offer high sensitivity without the cryogenics or magnetic shielding required by competing technologies. However, lack of compatibility with integrated photonics and electronics has posed a major barrier. Here we introduce silicon-on-insulator optomechanical magnetometers to address this barrier. A new post-release lithography process enables high-quality metallisation of released mechanical structures, overcoming the incompatibility between silicon-on-insulator fabrication and functional magnetic films. This allows us to employ photonic-crystal cavities that enhance motion-to-optical signal transduction by over an order of magnitude. The resulting devices achieve magnetic field sensitivity of 800 pT Hz^-1/2, three orders of magnitude beyond previous waveguide-integrated designs. The advances we report provide a path towards high-performance, room temperature and chip-integrated magnetometers for applications ranging from biomedical imaging and navigation to resource exploration.