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Room-Temperature Defect Qubits in Ultrasmall Nanocrystals

Dávid Beke, J. Valenta, Gyula Károlyházy, Sándor Lenk, Zsolt Czigány, Bence G. Márkus, K. Kamarás, Ferenc Simon, Ádám Gali

2020The Journal of Physical Chemistry Letters32 citationsDOIOpen Access PDF

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.

Topics & Concepts

NanocrystalQubitMaterials scienceNanotechnologyCondensed matter physicsPhysicsEngineering physicsQuantum mechanicsQuantumDiamond and Carbon-based Materials ResearchGraphene research and applicationsFullerene Chemistry and Applications