Synthesis of Phosphonium-Substituted Vinylidene Complexes from [HCCCH2PPh3]+: Exploring the Competition between Allene and Vinylidene Formation.

Reaction of the alkenyl-substituted carbene complex [Ru­(κ2-O2CMe)­(OC­{Me}­O­(CCHCH2)­(PPh3)2]+ with PPh3 results in the formation of the vinylidene-containing species [Ru­(κ1-O2CMe)­(κ2-O2CMe)­(CCHCH2PPh3)­(PPh3)2]+, among other products. This complex could also be obtained by reaction of [Ru­(κ2-O2CR)­(PPh3)2] (R = Me, Ph) with [HCCCH2PPh3]+ although in this instance competitive formation of allene-containing [Ru­(κ1-O2CR)­(κ2-O2CR)­(η2-H2CCCHPPh3)­(PPh3)2] occurred. Reaction of [Ru­(κ2-O2CMe)2(PPh3)2] with [H2CCCHPPh3]+ gives this allene complex in a selective fashion. Similar results were obtained when [RhCl­(PiPr3)2]2 was used as the metal precursor. The reaction with [H2CCCHPPh3]+ gave [RhCl­(η2-H2CCCHPPh3)­(PiPr3)2]+, whereas treatment with [HCCCH2PPh3]+ afforded a mixture of the same complex and [RhCl­(η2-HCCCH2PPh3)­(PiPr3)2]+, which subsequently isomerized to vinylidene-containing [RhCl­(CCHCH2PPh3)­(PiPr3)2]+ via the alkynyl hydride complex [RhCl­(H)­(CCCH2PPh3)­(PiPr3)2]+. Consistent with previous findings [HCCCH2PPh3]+ isomerizes to [H2CCCHPPh3]+ in the absence of a metal and the balance between the vinylidene and allene complexes formed in these reactions appears to relate to the efficiency of the reaction with each substrate.