Reactions of Laser-Ablated Uranium Atoms with H2O in Excess Argon:  A Matrix Infrared and Relativistic DFT Investigation of Uranium Oxyhydrides

Laser-ablated U atoms react with H2O during condensation in excess argon. Infrared absorptions at 1416.3, 1377.1, and 859.4 cm-1 are assigned to symmetric HUH, antisymmetric HUH, and UO stretching vibrations of the primary reaction product H2UO. Uranium monoxide, UO, also formed in the reaction...

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Bibliographic Details
Published in:Inorganic chemistry 2005-04, Vol.44 (7), p.2159-2168
Main Authors: Liang, Binyong, Hunt, Rodney D, Kushto, Gary P, Andrews, Lester, Li, Jun, Bursten, Bruce E
Format: Article
Language:English
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Summary:Laser-ablated U atoms react with H2O during condensation in excess argon. Infrared absorptions at 1416.3, 1377.1, and 859.4 cm-1 are assigned to symmetric HUH, antisymmetric HUH, and UO stretching vibrations of the primary reaction product H2UO. Uranium monoxide, UO, also formed in the reaction, inserts into H2O to produce HUO(OH), which absorbs at 1370.5, 834.3, and 575.7 cm-1. The HUO(OH) uranium(IV) product undergoes ultraviolet photoisomerization to a more stable H2UO2 uranium(VI) molecule, which absorbs at 1406.4 and 885.9 cm-1. Several of these species, particularly H2UO2, appear to form weak Ar-coordinated complexes. The predicted vibrational frequencies, relative absorption intensities, and isotopic shifts from relativistic DFT calculations are in good agreement with observed spectra, which further supports the identification of novel uranium oxyhydrides from matrix infrared spectra.
ISSN:0020-1669
1520-510X
DOI:10.1021/ic0483951