📝 SummarXiv

Abstract

Magnetometers based on nitrogen-vacancy (NV) centers in diamond have emerged as the most important solid-state quantum sensors. However, ensembles are limited in optical contrast to typically a few percent and high-sensitivity variants usually possess only a few $\mathrm{\mu}$T dynamic range. Here, we demonstrate a laser threshold magnetometry-based NV system that avoids these limitations. By integrating the NV centers into a laser cavity and showing magnetic-field-dependent shifts of the laser threshold, we observe 100\,\% contrast with strong output signals up to 50\,mW. The resulting system exhibits a dynamic range of $\pm$280\,$\mathrm{\mu}$T with a photon-shot-noise-limited sensitivity of 670\,fT/$\sqrt{\mathrm{Hz}}$, which we demonstrate to improve super-linearly with contrast. The ratio of these sensing-relevant parameters, that can be traded at the cost of each other, marks an improvement factor of 780 over typical fluorescence-based readout and vapor cell sensors. Such performance improvements open the door to new generations of sensors for applications including magnetoencephalography, magnetic navigation, and magnetic anomaly detection.