Chemical effects on nuclear decay of 235U isomer in the uranyl form

Abstract

The nucleus of uranium-235 (235U) possesses an exceptionally low-energy isomeric state, 235mU. Unlike most radioactive nuclides, whose nuclear-decay half-lives are constant, the half-life of 235mU varies with its chemical environment1,2 owing to interactions with outer-shell electrons in the internal-conversion (IC) process. However, the mechanism underlying this half-life variation, particularly the role of molecular bonding beyond simple electron-density effects1,2, remains unresolved. Here, we investigate variations in the half-lives of 235mU and the corresponding IC-electron energy spectra for uranyl (UO22+) compounds with different halide ligands. The half-lives of 235mU are measured to be 25.32(4), 26.05(8), 25.84(3), and 25.44(3) min for uranyl fluoride, chloride, bromide, and iodide, respectively, indicating that the half-life increases with increasing ligand electronegativity, with the exception of uranyl fluoride. The shortest half-life observed for uranyl fluoride is attributed to the smallest number of 6p electrons occupying bonding orbitals, as indicated by the IC-electron energy spectra and quantum chemical calculations. This work provides the first observation of a significant variation in a nuclear decay process driven by changes in molecular orbital formation, paving the way toward a deeper understanding of interactions between a nucleus and electrons involved in chemical bonding.

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