Multiple Modes for Coordination of Phenazine to Molybdenum: Ring Fusion Promotes Access to η⁴-Coordination, Oxidative Addition of Dihydrogen and Hydrogenation of Aromatic Nitrogen Compounds

Mo(PMe₃)₆ reacts with phenazine (PhzH) to give (η⁶-C₆-PhzH)Mo(PMe₃)₃, (μ-η⁶,η⁶-PhzH)[Mo(PMe₃)₃]₂ and (η⁴-C₄-PhzH)₂Mo(PMe₃)₂, each of which displays previously unknown coordination modes for phenazine. Both mononuclear (η⁶-C₆-PhzH)Mo(PMe₃)₃ and dinuclear (μ-η⁶,η⁶-PhzH)[Mo(PMe₃)₃]₂ react with H₂ at room temperature to give the respective dihydride complexes, (η⁴-C₄-PhzH)Mo(PMe₃)₃H₂ and (μ-η⁶,η⁴-PhzH)[Mo(PMe₃)₃][Mo(PMe₃)₃H₂]. A comparison of (η⁶-C₆-PhzH)Mo(PMe₃)₃ with the anthracene (AnH) and acridine (AcrH) counterparts, (η⁶-AnH)Mo(PMe₃)₃ and (η⁶-C₆-AcrH)Mo(PMe₃)₃, indicates that oxidative addition of H₂ is promoted by incorporation of nitrogen substituents into the central ring. Furthermore, comparison of (η⁶-C₆-PhzH)Mo(PMe₃)₃ with the quinoxaline (QoxH) analogue, (η⁶-C₆-QoxH)Mo(PMe₃)₃, indicates that ring fusion also promotes oxidative addition of H₂. The mononitrogen quinoline (QH) and acridine compounds, (η⁶-C₆-QH)Mo(PMe₃)₃ and (η⁶-C₆-AcrH)Mo(PMe₃)₃, which respectively possess two and three fused six-membered rings, exhibit a similar trend, with the former being inert towards H₂, while the latter reacts rapidly to yield (η⁴-C₄-AcrH)Mo(PMe₃)₃H₂. Ring fusion also promotes hydrogenation of the heterocyclic ligand, with (η⁶-C₆-AcrH)Mo(PMe₃)₃ releasing 9,10-dihydroacridine upon treatment with H₂ in benzene at 95 °C. Furthermore, catalytic hydrogenation of acridine to a mixture of 9,10-dihydroacridine and 1,2,3,4-tetrahydroacridine may be achieved by treatment of (η⁶-C₆-AcrH)Mo(PMe₃)₃ with acridine and H₂ at 95 °C.