Spin Catalysis in Photochemical Reactions and Its Applications to Quantum Information Nanotechnology
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Karagandy University of the name of acad. E.A. Buketov
Abstract
Chemistry as a science about spin and electric charge of micro particles which provide driving forces of
atomic interactions and molecular structure transformations fits pretty well to the modern Quantum Information
Science (QIS) requirements. Today’s computers operate only electric current signals in the semiconductor
networks but the electron-spin properties are not exploited in a large extend. Spintronics provides spinpolarized
currents and manipulates magnetic spin interactions; it uses mostly solid state chemistry of heavy
elements. But a rich organic chemistry of solvents and fin films offers a great potential for molecular electronics
and quantum computing. Photo-excited organic complexes of the “chromophore–radical” type provide
good promise for many technological applications in molecular spintronics and electronics, including QIS
technology. The doublet state photo excitation of stable organic radical being delocalized onto the linked anthracene
molecule within picoseconds and subsequently evolved into a quartet state for big radicals (a pure
high spin state) of the mixed radical-triplet character presents a sensible spin-optical interface for qubit in
quantum computing. This high-spin state is coherently addressable with EPR microwaves even at room temperature,
with the optical read-out induced by intersystem crossing (ISC) to emissive triplet state. Such integration
of radical luminescence and high-spin states EPR provides the organic materials involvement into
emerging QIS technologies.
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Minaev B.F.Spin Catalysis in Photochemical Reactions and Its Applications to Quantum Information Nanotechnology/B.F. Minaev//Eurasian Journal of Chemistry. – 2023. - Special Issue “Quantum Chemistry and Quantum Nanotechnologies of Materials”. - № 3(111). – pp.26-32.