Abstract
There is an urgent quest for room-temperature qubits in nanometer-sized, ultrasmall nanocrystals for quantum biosensing, hyperpolarization of biomolecules, and quantum information processing. Thus far, the preparation of such qubits at the nanoscale has remained futile. Here, we present a synthesis method that avoids any interaction of the solid with high-energy particles and uses self-propagated high-temperature synthesis with a subsequent electrochemical method, the no-photon exciton generation chemistry to produce room-temperature qubits in ultrasmall nanocrystals of sizes down to 3 nm with high yield. We first create the host silicon carbide (SiC) crystallites by high-temperature synthesis and then apply wet chemical etching, which results in ultrasmall SiC nanocrystals and facilitates the creation of thermally stable defect qubits in the material. We demonstrate room-temperature optically detected magnetic resonance signal of divacancy qubits with 3.5% contrast from these nanoparticles with emission wavelengths falling in the second biological window (1000–1380 nm). These results constitute the formation of nonperturbative bioagents for quantum sensing and efficient hyperpolarization.
Highlights
There is an urgent quest for room-temperature qubits in nanometer-sized, ultrasmall nanocrystals for quantum biosensing, hyperpolarization of biomolecules, and quantum information processing
Room-temperature defect qubits[2−4] stand out with their great potential in biology and human diagnosis, by means of sensing at the nanoscale[5] and hyperpolarization of biomolecules.[6]. The state of these defect qubits is read out by optical means which harness the spin-selective fluorescence of the defect qubits: the electron spin state can be manipulated by applying a resonant microwave field while monitoring changes in the fluorescence
optically detected magnetic resonance (ODMR) signals from defect qubits have been either reported from 7.5 nm diamond nanocrystals, which were created by milling of larger crystals and subsequent electron irradiation,[13] or detected in some 5 nm particles separated from detonation nanodiamonds by ultracentrifugation.[14]
Summary
D.B. contributed to the sample preparation, analysis of the EPR spectra, TEM, AFM, DLS results, PL, single dot PL, and ODMR measurements and analysis. J.V. carried out the single dot measurements and supervised the analysis. Gy.K. contributed to the sample preparation, PL, and EPR measurements. S.L. carried out the atomic force microscopy measurements. Zs.Cz. carried out high-resolution transmission electron microscopy measurements. B.G.M. recorded the EPR spectra under F.S.’s supervision. A.G. conceived the research project and wrote the manuscript with D.B. All authors commented on the manuscript
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