DFT study of the reactivity of methane and dioxygen with d-L2M complexes

A density functional theory analysis of the reactions of methane and O₂ with d¹⁰-L₂M complexes (M = Pd, Pt; L = N-heterocyclic carbene (NHC), PMe₃) is presented. Computations suggest that reaction of L₂M⁰ with O₂/CH₄ to form cis- (L)₂M(OOH)(CH₃) is only slightly uphill (ΔG ∼ 10-11 kcal/mol). Based on calculated thermodynamics, reaction of (L)₂Pt⁰ with CH₄ and O₂ is predicted to be more favorable by first addition of CH₄ and then reaction of O₂ with the resulting methyl-hydrido complex. However, oxidative addition for either the C-H bond of methane or of O₂ to d¹⁰-L₂M complexes is kinetically prohibitive. If barriers to oxidative addition to d¹⁰-L₂M systems could be reduced, conversion of L₂M(H)(CH₃) to L₂M(OOH)(CH₃) via hydrogen atom abstract/radical rebound is calculated to be thermodynamically and kinetically feasible, particularly for NHC and Pd. As (NHC)₂Pd also has a lower free energy to methane C-H oxidative addition than does (NHC)₂Pt, the former combination would appear to be a promising starting point in the search for catalysts for partial hydrocarbon oxidation.