Helena S. Knowles

Demonstration of a Coherent Electronic Spin Cluster in Diamond

An obstacle for spin-based quantum sensors is magnetic noise due to proximal spins. However, a cluster of such spins can become an asset, if it can be controlled. Here, we polarize and readout a cluster of three nitrogen electron spins coupled to a single nitrogen-vacancy spin in diamond. We further achieve sub-nm localization of the cluster spins. Finally, we demonstrate coherent spin exchange between the species by simultaneous dressing of the nitrogen-vacancy and the nitrogen states. These results establish the feasibility of environment-assisted sensing and quantum simulations with diamond spins.

A coherent electron spin cluster in diamond for environment-assisted magnetometry

Optically active spins in solid-state are of interest for their potential use in a variety of future technologies. These range from quantum information processors to magnetic and electric field sensors at the nanoscale. Typically, dark paramagnetic spins in the solid-state host lattice cause quantum decoherence of the bright spin of interest. However, if these dark spins can be brought under control they can be a resource. For example, nuclear spins in the vicinity of an optically active spin can be used as local quantum registers [1] for quantum error correction and entanglement distillation.

Nanodiamond preparation and surface characterization for biological applications

Nanodiamonds contain stable fluorescent emitters and hence can be used for molecular fluorescence imaging and precision sensing of electromagnetic fields. The physical properties of these emitters together with their low reported cytotoxicity make them attractive for biological imaging applications. The controlled application of nanodiamonds for cellular imaging requires detailed understanding of surface chemistry, size ranges and aggregation, as these can all influence cellular interactions. We compared these characteristics for graphitic and oxidized nanodiamonds. Oxidation is generally used for surface functionalization, and was optimized by Thermogravimetric Analysis, achieved by 445±5°C heating in air for 5 hours, then confirmed via Raman and Infrared spectroscopies. Size ranges and aggregation were assessed using Atomic Force Microscopy and Dynamic Light Scattering. Biocompatibility in breast cancer cell lines was measured using a proliferation assay. Heating at 445±5°C reduced the Raman signal of graphitic carbon (1575 cm-1) as compared to that of diamond (1332 cm-1) from 0.31±0.07 Raman intensity units to 0.07±0.04. This temperature was substantially below the onset of major mass loss (observed at 535±1°C) and therefore achieved cost efficiency, convenience and high yield. Graphitic and oxidized nanodiamonds formed aggregates in water, with a mean particle size of 192±4nm and 166±2nm at a concentration of 66μg/mL. We then applied the graphitic and oxidized nanodiamonds to cells in culture at 1μg/mL and found no significant change in the proliferation rate (-5±2% and -1±3% respectively). Nanodiamonds may therefore be suitable for development as a novel transformative tool in the life sciences.

Controlling a nuclear spin in a nanodiamond

The sensing capability of a single optically bright electronic spin in diamond can be enhanced by making use of proximal dark nuclei as ancillary spins. Such systems, so far only realized in bulk diamond, provide orders of magnitude higher sensitivity and spectral resolution in the case of magnetic sensing, as well as improved readout fidelity and state storage time in quantum information schemes. In nanodiamonds, which offer additional opportunities as mobile nanoscale sensors, electronic-nuclear spin complexes have remained inaccessible. We demonstrate coherent control of a 13C nuclear spin located 4{\AA} from a nitrogen-vacancy center in a nanodiamond and show quantum-state transfer between the two components of this hybrid spin system. We extract a nuclear-spin free precession time of T2* = 26 us, which exceeds the bare electron free precession time in nanodiamond by two orders of magnitude.

Observing bulk spin coherence in high-purity nanodiamonds

Nitrogen-vacancy centers in nanodiamond allow nano-resolution magnetometry. However, their use has been limited by poor quantum state coherence times. Using high purity nanodiamonds we achieve spin coherence comparable to that in bulk diamond.

Single Spins in Diamond for Nanoscale MRI

Nitrogen-vacancy centres in nanodiamond allow nano-resolution magnetometry. However, their use has been limited by poor quantum state coherence times. Using high purity nanodiamonds we achieve spin coherence comparable to that in bulk diamond.