A unified mechanism for the stoichiometric reduction of H+ and C2H2 by [Fe4S4(SPh)4]3– in MeCN

Abstract

The kinetics and mechanisms of the conversions of H⁺ into H₂ and C₂H₂ into C₂H₄ by [Fe₄S₄(SPh)₄]^3–, using [Hlut]⁺ (lut = 2,6-dimethylpyridine) as the proton source, have been investigated in MeCN. At high concentrations of [Hlut]⁺, [Fe₄S₄(SPh)₄]^3– rapidly binds three protons to give [Fe₄S₂(SH)₂(SPh)₃(SHPh)], and it is only in this protonation state that the cluster is capable of transforming the substrates. Kinetic studies indicated that subsequent dissociation of the thiol from [Fe₄S₂(SH)₂(SPh)₃(SHPh)] to generate [Fe₄S₂(SH)₂(SPh)₃] is also essential for H₂ and C₂H₄ production. It is proposed that the vacant site on one of the Fe atoms allows protonation of this Fe by [Hlut]⁺ to form [Fe₄HS₂(SH)₂(SPh)₃]⁺. Reduction of this species by another molecule of reduced cluster {probably [Fe₄S₂(SH)₂(SPh)₃(SHPh)]} gives the “super-reduced” cluster [Fe₄HS₂(SH)₂(SPh)₃] {and [Fe₄S₂(SH)₂(SPh)₃(SHPh)]⁺}. Subsequently the “super-reduced” cluster releases H₂ and produces [Fe₄S₂(SH)₂(SPh)₃(SHPh)]⁺. In the presence of C₂H₂, [Fe₄HS₂(SH)₂(SPh)₃]⁺ binds the alkyne to form [Fe₄HS₂(SH)₂(SPh)₃(C₂H₂)]⁺. Subsequent reduction (as above) produces the “super-reduced” [Fe₄HS₂(SH)₂(SPh)₃(C₂H₂)], then C₂H₄. However, binding C₂H₂ does not completely suppress H₂ formation and [Fe₄HS₂(SH)₂(SPh)₃(C₂H₂)] produces H₂ca. 30% of the time. The results of earlier studies on the reduction of H⁺ and C₂H₂ by structurally analogous Fe–S-based clusters are discussed and shown to be consistent with this mechanism.