Nanoscale NMR Spectroscopy using Self-Calibrating Nanodiamond Quantum Sensors

Abstract: Conventional nuclear magnetic resonance (NMR) spectroscopy relies on acquiring signal from a macroscopic ensemble of molecules to gain information about molecular structure and dynamics. Transferring this technique to nanoscale sample sizes would enable molecular analysis without the effects of averaging over spatial and temporal inhomogeneities and without the need for macroscopic volumes of analyte, both inherent to large ensemble measurements. Nanoscale NMR based on nitrogen vacancy (NV) centers inside bulk diamond chips achieves single nuclear spin sensitivity and the resolution required to determine chemical structure, but their detection volume is limited to a few nanometers above the diamond surface for the most sensitive devices. This precludes them from use for nuclear spin sensing with nanoscale resolution inside thicker structures, such as cells. Here, we demonstrate the detection of NMR signals from multiple nuclear species in a (19 nm)3 volume using versatile NV-NMR devices inside nanodiamonds that have a typical 30 nm diameter. The devices detect a signal generated by a small number of analyte molecules on the order of 1000. To use these devices in situ, the detected signal must be corrected for the unknown geometry of each nanodiamond device. We show that such a calibration could be performed by exploiting the signal from a thin layer of nuclei on the diamond surface. These results, combined with the low toxicity of nanodiamonds and their amenability to surface functionalization, indicate that nanodiamond NV-NMR devices could become a useful tool for nanoscale NMR-based sensing inside living cells.