Syntheses, Structures, and DFT Calculations of Phosphenium Phosphite Complexes of Molybdenum:  Preference of Nonbridging Form to Bridging Form of a Donor Group

Molybdenum carbonyl complexes with two and three diamino-substituted phosphites, cis-[Mo(CO)₄{P(NMeCH₂)₂(OMe)}₂] (1a) and fac-[Mo(CO)₃{P(NMeCH₂)₂(OMe)}₃] (2a), react with TMSOTf to give the corresponding cationic phosphenium phosphite complexes, cis-[Mo(CO)₄{P(NMeCH₂)₂(OMe)}{P(NMeCH₂)₂}](OTf) (1b) and fac-[Mo(CO)₃{P(NMeCH₂)₂(OMe)}₂{P(NMeCH₂)₂}](OTf) (2b), respectively, by single OMe^- abstraction from the coordinating phosphite. The X-ray structure analyses and the NMR spectra of the products showed that the original configuration around the Mo is retained with the OMe group(s) on the remaining phosphite ligand(s) free from the interaction with the phosphenium phosphorus. A related phosphite complex, CpMo(CO)(I){P(NMeCH₂)₂(OMe)}₂ (3), was converted in the reaction with NaK_2.8 into a neutral phosphenium complex, CpMo(CO){P(NMeCH₂)₂(OMe)}{P(NMeCH₂)₂} (4), in which no such significant MeO···P (phosphenium) bridging interaction was also observed. DFT calculations have been incorporated to study the preference of the nonbridging form for phosphenium phosphite complexes, together with the preference of the bridging form for the analogous silylene alkoxysilyl complexes, and revealed that the bridging requires larger geometrical changes for phosphenium phosphite complexes than for silylene alkoxysilyl complexes.