Reactivity of Iridium Complexes of a Triphosphorus-Pincer Ligand Based on a Secondary Phosphine. Catalytic Alkane Dehydrogenation and the Origin of Extremely High Activity

Abstract: The selective functionalization of alkanes and alkyl groups is a major goal of chemical catalysis. Toward this end, a bulky triphosphine with a central secondary phosphino group, bis­(2-di-t-butyl-phosphinophenyl)­phosphine (tBuPHPP), has been synthesized. When complexed to iridium, it adopts a meridional (“pincer”) configuration. The secondary phosphino H atom can undergo migration to iridium to give an anionic phosphido-based–pincer (tBuPPP) complex. Stoichiometric reactions of the (tBuPPP)Ir complexes refle… Show more

“…High yields, 87-97%, of the corresponding alcohols are formed in short times, with turnover frequency values at 50% conversion between 1011 and 1960 h À1 , with 0.2 mol% of catalyst, at 80 1C (Scheme 25). 141 The bifunctional systems formed by the osmium(IV)polyhydrides 18 and OsH 3 {k 3 -P,N,P-[N(CH 2 CH 2 P i Pr 2 )]} (61) and the iridium(III) complexes 48 and 49 catalyze at room temperature the hydrogen transfer from primary and secondary alcohols to acetophenone and cyclohexanone, in principle, via a b-type outer sphere mechanism. Both osmium and iridium systems display comparable activities, whereas the turnover frequencies in ethanol are lower than in 2-propanol.…”

“…60 Goldman and coworkers have recently reported an IrH 3 ( P , P , P ) system, which is two orders of magnitude more active than the IrH x ( P , C , P ) ( x = 2, 4) complexes for the alkane dehydrogenation in the presence of a hydrogen acceptor. 61 The introduction of a heteroatom into the ring system significantly decreases the enthalpy of dehydrogenation. 62–64 As a consequence, the metal-promoted acceptorless dehydrogenation of cyclic amines are receiving noticeable attention.…”

Homogeneous catalysis with polyhydride complexes

“…High yields, 87-97%, of the corresponding alcohols are formed in short times, with turnover frequency values at 50% conversion between 1011 and 1960 h À1 , with 0.2 mol% of catalyst, at 80 1C (Scheme 25). 141 The bifunctional systems formed by the osmium(IV)polyhydrides 18 and OsH 3 {k 3 -P,N,P-[N(CH 2 CH 2 P i Pr 2 )]} (61) and the iridium(III) complexes 48 and 49 catalyze at room temperature the hydrogen transfer from primary and secondary alcohols to acetophenone and cyclohexanone, in principle, via a b-type outer sphere mechanism. Both osmium and iridium systems display comparable activities, whereas the turnover frequencies in ethanol are lower than in 2-propanol.…”

“…60 Goldman and coworkers have recently reported an IrH 3 ( P , P , P ) system, which is two orders of magnitude more active than the IrH x ( P , C , P ) ( x = 2, 4) complexes for the alkane dehydrogenation in the presence of a hydrogen acceptor. 61 The introduction of a heteroatom into the ring system significantly decreases the enthalpy of dehydrogenation. 62–64 As a consequence, the metal-promoted acceptorless dehydrogenation of cyclic amines are receiving noticeable attention.…”

Homogeneous catalysis with polyhydride complexes

“…( tBu P H PP)IrH 3 ( tBu P H PP = bis(2-di-i-butyl-phosphinophenyl)phosphine; Scheme ) was recently reported to act as a precursor of the catalytically active fragment ( tBu PPP)Ir, which dehydrogenated n -alkanes with the use of sterically unhindered terminal alkenes as hydrogen acceptors at temperatures as low as 80 °C . This exceptionally high activity, however, was not apparent when using the COA/TBE benchmark transfer dehydrogenation couple.…”

“…With the use of 1-hexene as the hydrogen acceptor, for example, 60 mM octenes was obtained after 6 min at 100 °C under the same conditions . When propene was used as the acceptor, we typically conducted the reaction at 80 °C; even at that low temperature, for example, 78 mM octenes was obtained after 30 min …”

“…This explanation would clearly follow if hydrogenation of the acceptor is the rate-determining step and the catalyst resting state is a hydrogenated form which reacts with the acceptor, e.g., ( tBu PPP)IrH 2 . However, NMR observations indicate that this is not the case; instead, the resting state appears to be a dehydrogenated form, generally ( tBu PPP)Ir(olefin) . Further evidence that the reaction rate is not simply equal to the rate of the reaction of a hydrogenated complex (e.g., ( tBu PPP)IrH 2 ) with the acceptor is obtained from experiments with COA.…”

High Activity and Selectivity for Catalytic Alkane–Alkene Transfer (De)hydrogenation by (^tBuPPP)Ir and the Importance of Choice of a Sacrificial Hydrogen Acceptor

Solid catalysts for the dehydrogenation of long-chain alkanes: lessons from the dehydrogenation of light alkanes and homogeneous molecular catalysis