Abstract Spin defects in solids offer promising platforms for quantum sensing and memory due to their long coherence times and compatibility with quantum networks. Here, we integrate a single nitrogen vacancy (NV) center in diamond with scanning probe microscopy to discover, read out, and spatially map arbitrary spin-based quantum sensors at the nanoscale. Using the boron vacancy (VB-) center in hexagonal boron nitride—an emerging two-dimensional spin system—as a model, we detect its electron spin resonance through changes in the spin relaxation time (T1) of a nearby NV center, without requiring direct optical excitation or readout of the VB- fluorescence. Cross relaxation between the NV and VB- ensembles results in a pronounced NV T1 reduction, enabling nanoscale mapping of spin defect distributions beyond the optical diffraction limit. This approach highlights NV centers as versatile quantum probes for characterizing spin systems, including those emitting at wavelengths beyond the range of silicon-based detectors. Our results open a pathway to hybrid quantum architectures where sensing and readout qubits are decoupled, facilitating the discovery of otherwise inaccessible quantum defects for advanced sensing and quantum networking.
Zhao et al. (Fri,) studied this question.
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