Vector magnetometry using cavity-enhanced microwave readout in nitrogen-vacancy diamond

TL;DR

This paper presents a novel vector magnetometer using NV centers in diamond coupled with a microwave cavity, achieving high contrast and sensitivity without bulky optical components.

Contribution

It introduces a cavity-enhanced microwave readout method for NV centers enabling efficient vector magnetic field sensing with improved contrast and simplified optical setup.

Findings

Achieved 40% contrast in spin-state readout.

Demonstrated a sensitivity of 250 pT/√Hz from DC to 1 kHz.

Predicted a thermal noise limit of 2 pT/√Hz.

Abstract

We demonstrate $4\pi$-steradian vector magnetic field sensing using an ensemble of nitrogen-vacancy (NV) centers in a single-crystal diamond coupled to a microwave (MW) cavity. The MW cavity enhances the spin-photon coupling which enables efficient, high-contrast spin-state readout via MW interrogation and removes the need for bulky optical collection components. An applied AC bias magnetic field lifts the zero-field degeneracy of the four crystallographic NV orientations, allowing each orientation to be individually addressed and used for vector reconstruction of the magnetic field. The resulting magnetometer has a 40\% contrast (20x higher than typical for optical spin-ensemble readout) and achieves a single-axis sensitivity of 250 pT/$\sqrt{\mathrm{Hz}}$ which is flat from DC to 1 kHz. Noise models of the composite spin-cavity system establish MW amplitude noise as the dominant noise source and predict a thermal noise limit of 2 pT/$\sqrt{\mathrm{Hz}}$.