Issue 10, 2015

Protonation of bridging sulfur in cubanoid Fe4S4 clusters causes large geometric changes: the theory of geometric and electronic structure.

Abstract

Density functional calculations indicate that protonation of a μ3-S atom in cubanoid clusters [Fe4S4X4]2− leads to a large extension of one Fe–S(H) bond such that the SH ligand is doubly-bridging, μ-SH. Triply-bridging SH in these clusters is unstable, relative to μ-SH. The theory for the geometric and electronic structures of the protonated [Fe4S4X4]2− clusters (X = Cl, SEt, SMe, SPh, OMe, OPh) is presented in this paper. The principal results are (1) the unique Fe atom in [Fe4S3(SH)X4] is three-coordinate, with planar or approximately planar stereochemistry, (2) approximately equi-energetic endo and exo isomers occur for pyramidal μ-SH, (3) the structural changes caused by protonation reverse without barrier on deprotonation, (4) the most stable electronic states have S = 0 and oppositely signed spin densities on the Fe atoms bearing the μ-SH bridge, (5) interconversions between endo and exo isomers, and between ground and excited states, occur through concerted lengthenings and shortenings of Fe–S(H) interactions, on relatively flat energy surfaces, (6) protonation of an X ligand does not change the characteristics of protonation of μ3-S. Experimental tests of this theory are suggested, and applications discussed.

Graphical abstract: Protonation of bridging sulfur in cubanoid Fe4S4 clusters causes large geometric changes: the theory of geometric and electronic structure.

Supplementary files

Article information

Article type
Paper
Submitted
01 Dec 2014
Accepted
27 Jan 2015
First published
09 Feb 2015

Dalton Trans., 2015,44, 4707-4717

Author version available

Protonation of bridging sulfur in cubanoid Fe4S4 clusters causes large geometric changes: the theory of geometric and electronic structure.

I. Dance, Dalton Trans., 2015, 44, 4707 DOI: 10.1039/C4DT03681F

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