Robust Spin Relaxometry with Fast Adaptive Bayesian Estimation

Spin relaxometry with nitrogen-vacancy (N -V) centers in diamond offers a spectrally selective, atomically localized, and calibrated measurement of microwave-frequency magnetic noise, presenting a versatile probe for condensed-matter and biological systems. Typically, relaxation rates are estimated with curve-fitting techniques that do not provide optimal sensitivity, often leading to long acquisition times that are particularly detrimental in systems prone to drift or other dynamics of interest. Here we show that adaptive Bayesian estimation is well suited to this problem, producing dynamic relaxometry pulse sequences that rapidly find an optimal operating regime. In many situations (including the system we employ), this approach can speed the acquisition by an order of magnitude. We also present a four signal measurement protocol that is robust to drifts in spin readout contrast, polarization, and microwave pulse fidelity while still achieving near-optimal sensitivity. The combined technique offers a practical, hardware-agnostic approach for a wide range of N -V relaxometry applications.

Automated summary

Spin relaxometry with nitrogen-vacancy (N-V) centers in diamond is a versatile probe for condensed-matter and biological systems, offering a spectrally selective, atomically localized, and calibrated measurement of microwave-frequency magnetic noise. Adaptive Bayesian estimation and a four signal measurement protocol are proposed to optimize the sensitivity and speed up the acquisition process. The combined technique provides a practical and hardware-agnostic approach for a wide range of N-V relaxometry applications.