Spectroscopic detection and theoretical confirmation of the role of Cr ₂(CO)₅(C₅R₅)₂ and ·Cr(CO)₂(ketene)(C₅R₅) as intermediates in carbonylation of N=N=CHSiMe₃ to O=C=CHSiMe₃ by ·Cr(CO)₃(C₅R₅) (R = H, CH₃)

Conversion of N=N=CHSiMe₃ to O=C=CHSiMe₃ by the radical complexes ·Cr(CO)₃C₅R₅ (R = H, CH₃) derived from dissociation of [Cr(CO)₃(C ₅R₅)]₂ have been investigated under CO, Ar, and N₂ atmospheres. Under an Ar or N₂ atmosphere the reaction is stoichiometric and produces the Cr≡Cr triply bonded complex [Cr(CO)₂(C₅R₅)]₂. Under a CO atmosphere regeneration of [Cr(CO)₃(C₅R₅)] ₂ (R = H, CH₃) occurs competitively and conversion of diazo to ketene occurs catalytically as well as stoichiometrically. Two key intermediates in the reaction, ·Cr(CO)₂(ketene)(C ₅R₅) and Cr₂(CO)₅(C ₅R₅)₂ have been detected spectroscopically. The complex ·Cr(¹³CO)₂(O=¹³C=CHSiMe ₃)(C₅Me₅) has been studied by electron spin resonance spectroscopy in toluene solution: g(iso) = 2.007; A(⁵³Cr) = 125 MHz; A(¹³CO) = 22.5 MHz; A(O=¹³C=CHSiMe₃) = 12.0 MHz. The complex Cr₂(CO)₅(C₅H ₅)₂, generated in situ, does not show a signal in its ¹H NMR and reacts relatively slowly with CO. It is proposed to be a ground-state triplet in keeping with predictions based on high level density functional theory (DFT) studies. Computed vibrational frequencies are also in good agreement with experimental data. The rates of CO loss from ³Cr₂(CO)₅-(C₅H₅) ₂ producing ¹[Cr(CO)₂(C₅H ₅)]₂ and CO addition to ³Cr₂(CO) ₅(C₅H₅)₂ producing ¹[Cr(CO)₃(C₅H₅)]₂ have been measured by kinetics and show ΔH^† ≅ 23 kcal mol^-1 for both processes. Enthalpies of reduction by Na/Hg under CO atmosphere of [Cr(CO)ⁿ(C₅H₅)]₂ (n = 2,3) have been measured by solution calorimetry and provide data for estimation of the Cr≡Cr bond strength in [Cr(CO)₂(C₅H ₅)]₂ as 72 kcal mol^-1. The complex [Cr(CO) ₂(C₅H₅)]₂ does not readily undergo ¹³CO exchange at room temperature or 50°C implying that ³Cr₂(CO)₅(C₅H₅) ₂ is not readily accessed from the thermodynamically stable complex [Cr(CO)₂(C₅H₅)]₂. A detailed mechanism for metalloradical based conversion of diazo and CO to ketene and N₂ is proposed on the basis of a combination of experimental and theoretical data.