Optically detected flip-flops between different spin ensembles in diamond

We employ the technique of optical detection of magnetic resonance to study dipolar interaction in diamond between nitrogen-vacancy color centers of different crystallographic orientations and substitutional nitrogen defects. We demonstrate optical measurements of resonant spin flip-flips (second Larmor line), and flip-flops between different spin ensembles in diamond. In addition, the strain coupling between the nitrogen-vacancy color centers and bulk acoustic modes is studied using optical detection. Our findings may help optimize cross-polarization protocols, which, in turn, may allow improving the sensitivity of diamond-based detectors.

Automated summary

The study uses optical detection of magnetic resonance to investigate dipolar interaction in diamond between nitrogen-vacancy color centers of different crystallographic orientations and substitutional nitrogen defects. Optical measurements of resonant spin flip-flips and flip-flops between different spin ensembles in diamond are demonstrated. The findings could aid in optimizing cross-polarization protocols to enhance the sensitivity of diamond-based detectors.