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Hexacarbonyldiplatinum(I). Synthesis, Spectroscopy, and Density Functional Calculation of the First Homoleptic, Dinuclear Platinum(I) Carbonyl Cation, [{Pt(CO)3}2]2+, Formed in Concentrated Sulfuric Acid

The dissolution of PtO2 in concentrated H2SO4 under an atmosphere of CO results in the formation of hexacarbonyldiplatinum(I), [{Pt(CO)3}2]2+ (1), the first homoleptic, dinuclear, cationic platinum carbonyl complex, of which a prolonged evacuation leads to reversible disproportionation to give cis-[...

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Bibliographic Details
Published in:Journal of the American Chemical Society 2000-07, Vol.122 (29), p.6862-6870
Main Authors: Xu, Qiang, Heaton, Brian T, Jacob, Chacko, Mogi, Koichi, Ichihashi, Yuichi, Souma, Yoshie, Kanamori, Kan, Eguchi, Taro
Format: Article
Language:English
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Summary:The dissolution of PtO2 in concentrated H2SO4 under an atmosphere of CO results in the formation of hexacarbonyldiplatinum(I), [{Pt(CO)3}2]2+ (1), the first homoleptic, dinuclear, cationic platinum carbonyl complex, of which a prolonged evacuation leads to reversible disproportionation to give cis-[Pt(CO)2]2+ (solv) (2) and Pt(0). 1 has been completely characterized by NMR (13C and 195Pt), IR, Raman, and EXAFS spectroscopy. The structure of 1 is rigid on the NMR time scale at room temperature. NMR:  δ(13CA) 166.3, δ(13CB) 158.7, δ(195Pt) −211.0 ppm; 1 J(Pt−CA) = 1281.5 Hz, 1 J(Pt−CB) = 1595.7 Hz, 1 J(Pt−Pt‘) = 550.9 Hz. The strongly polarized, sharp Raman band at 165 cm-1 (ρ = ca. 0.25) indicates the presence of a direct Pt−Pt bond. The IR and Raman spectra in the CO stretching region are entirely consistent with the presence of only terminal CO's on a nonbridged Pt−Pt bond with D 2 d symmetry. ν(CO)IR:  2174 (E), 2187 (B 2), and 2218 cm-1 (B 2); ν(CO)Raman:  2173 (E), 2194 (B 2), 2219 (B 2), 2209 (A 1) and 2233 cm-1 (A 1). EXAFS measurements show that the Pt−Pt bond is 2.718 Å and the mean length of the Pt−C bonds is 1.960 Å. The geometric optimization for 1 by a density functional calculation at the B3LYP level of theory predicts that the dinuclear cation contains two essentially planar tricarbonyl platinum(I) units that are linked via a Pt−Pt bond about which they are twisted by exactly 90.0° with respect to each other.
ISSN:0002-7863
1520-5126
DOI:10.1021/ja000716u