Mechanistic Studies of O₂ Reduction Effected by Group 9 Bimetallic Hydride Complexes

Synthetic and kinetic studies are used to uncover mechanistic details of the reduction of O₂ to water mediated by dirhodium complexes. The mixed-valence Rh₂^0,II(tfepma)₂(CN^tBu)₂Cl₂ (1, tfepma = MeN[P(OCH₂CF₃)₂]₂, CN^tBu = tert-butyl isocyanide) complex is protonated by HCl to produce Rh₂^II,II(tfepma)₂(CN^tBu)₂Cl₃H (2), which promotes the reduction of O₂ to water with concomitant formation of Rh₂^II,II(tfepma)₂(CN^tBu)₂Cl₄ (3). Reactions of the analogous diiridium complexes permit the identification of plausible reaction intermediates. Ir₂^0,II(tfepma)₂(CN^tBu)₂Cl₂ (4) can be protonated to form the isolable complex Ir₂^II,II(tfepma)₂(CN^tBu)₂Cl₃H (5), which reacts with O₂ to form Ir₂^II,II(tfepma)₂(CN^tBu)₂Cl₃(OOH) (6). In addition, 4 reacts with O₂ to form Ir₂^II,II(tfepma)₂(CN^tBu)₂Cl₂(η²-O₂) (7), which can be protonated by HCl to furnish 6. Complexes 6 and 7 were both isolated in pure form and structurally and spectroscopically characterized. Kinetics examination of hydride complex 5 with O₂ and HCl furnishes a rate law that is consistent with an HCl-elimination mechanism, where O₂ binds an Ir⁰ center to furnish an intermediate η²-peroxide intermediate. Dirhodium congener 2 obeys a rate law that not only is also consistent with an analogous HCl-elimination mechanism but also includes terms indicative of direct O₂ insertion and a unimolecular isomerization prior to oxygenation. The combined synthetic and mechanistic studies bespeak to the importance of peroxide and hydroperoxide intermediates in the reduction of O₂ to water by dirhodium hydride complexes.