Hyperfine Structure and Exchange Coupling of Vacancy-Induced Ce3+ Spin Centers in Nuclear-Spin-Dilute CeO2

Abstract

Oxygen vacancies in ceria CeO2 donate electrons that localize as Ce3+ (4f1, S=1/2) small polarons, creating rare-earth spin centers through native defect chemistry rather than implantation or extrinsic doping. We investigate the magnetic environment of these centers using first-principles PBE+U calculations with a linear-response Hubbard parameter (U=5.8382 eV), hyperfine tensors from the all-electron reconstruction of the projector-augmented-wave method, and Korringa-Kohn-Rostoker exchange calculations within the coherent-potential approximation. Four vacancy configurations spanning concentrations from 3.125\% to 12.5\% are considered. A distinctive feature of the host follows from cerium isotopics: all naturally occurring cerium isotopes possess nuclear spin I=0, eliminating on-site hyperfine interactions at the Ce3+ center and leaving the nuclear-spin bath entirely on the oxygen sublattice, whose sole magnetic isotope, 17O (I=5/2), occurs at 0.038\% natural abundance. The resulting 17O hyperfine landscape consists of a small number of strongly coupled, nearly axial first-shell nuclei with contact couplings reaching 6~MHz, surrounded by a weakly coupled and strongly anisotropic outer shell. These tensors define experimentally accessible signatures for 17O ESEEM and HYSCORE measurements and provide the microscopic hyperfine parameters required for cluster-correlation-expansion calculations of spin coherence. Exchange interactions between neighboring polarons are weak and oxygen-mediated, leaving the vacancy-generated spins largely independent over the concentration range considered. Together, these results establish oxygen-deficient CeO2 as a chemically generated and intrinsically nuclear-spin-dilute host for rare-earth spin centers, and provide the first-principles magnetic parameters needed to assess their coherence properties.

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