Oxidation Studies of Dipositive Actinide Ions, An2+ (An = Th, U, Np, Pu, Am) in the Gas Phase: Synthesis and Characterization of the Isolated Uranyl, Neptunyl, and Plutonyl Ions UO22+(g), NpO22+(g), and PuO22+(g)

Abstract

Reactions of atomic and ligated dipositive actinide ions, An²⁺, AnO²⁺, AnOH²⁺, and AnO₂²⁺ (An = Th, U, Np, Pu, Am) were systematically studied by Fourier transform ion cyclotron resonance mass spectrometry. Kinetics were measured for reactions with the oxidants, N₂O, C₂H₄O (ethylene oxide), H₂O, O₂, CO₂, NO, and CH₂O. Each of the five An²⁺ ions reacted with one or more of these oxidants to produce AnO²⁺, and reacted with H₂O to produce AnOH²⁺. The measured pseudo-first-order reaction rate constants, k, revealed disparate reaction efficiencies, k/k_COL: Th²⁺ was generally the most reactive and Am²⁺ the least. Whereas each oxidant reacted with Th²⁺ to give ThO²⁺, only C₂H₄O oxidized Am²⁺ to AmO²⁺. The other An²⁺ exhibited intermediate reactivities. Based on the oxidation reactions, bond energies and formation enthalpies were derived for the AnO²⁺, as were second ionization energies for the monoxides, IE[AnO⁺]. The bare dipositive actinyl ions, UO₂²⁺, NpO₂²⁺, and PuO₂²⁺, were produced from the oxidation of the corresponding AnO²⁺ by N₂O, and by O₂ in the cases of UO²⁺ and NpO²⁺. Thermodynamic properties were derived for these three actinyls, including enthalpies of formation and electron affinities. It is concluded that bare UO₂²⁺, NpO₂²⁺, and PuO₂²⁺ are thermodynamically stable toward Coulomb dissociation to {AnO⁺ + O⁺} or {An⁺ + O₂⁺}. It is predicted that bare AmO₂²⁺ is thermodynamically stable. In accord with the expected instability of Th(VI), ThO²⁺ was not oxidized to ThO₂²⁺ by any of the seven oxidants. The gas-phase results are compared with the aqueous thermochemistry. Hydration enthalpies were derived here for uranyl and plutonyl; our ΔH_hyd[UO₂²⁺] is substantially more negative than the previously reported value, but is essentially the same as our ΔH_hyd[PuO₂²⁺].