Abstract
Bimetallic structures of the general type [M2(µ-S)2] are omnipresent in nature, for biological function [M2(µ-S)2] sites interconvert between electronically distinct, but isostructural, forms. Different from structure-function relationships, the current understanding of the mechanism of formation and persistence of [M2(µ-S)2] sites is poorly developed. This work reports on bimetallic model compounds of nickel that interconvert between functional structures [Ni2(µ-S)2]+/2+ and isomeric congeners [2{κ-S–Ni}]2+/+, S = Aryl-S−, in which the nickel ions are geometrically independent. Interconversion of the two sets of structures was studied quantitatively by UV–VIS absorption spectroscopy and cyclic voltammetry. Assembly of the [Ni2(µ-S)2]+ core from [2{κ-S–Ni}]+ is thermodynamically and kinetically highly preferred over the disassembly of [Ni2(µ-S)2]2+ into [2{κ-S–Ni}]2+. Labile Ni-η2/3-bonding to aromatic π-systems of the primary thiophenol ligand is critical for modeling (dis)assembly processes. A phosphine coligand mimics the role of anionic donors present in natural sites that saturate metal coordination. Three parameters have been identified as critical for structure formation and persistence. These are, first, the stereoelectronic properties of the metals ions, second, the steric demand of the coligand, and, third, the properties of the dative bond between nickel and coligand. The energies of transition states connecting functional and precursor forms have been found to depend on these parameters.
Highlights
Sulphur-bridged bimetallic structures of the general formula [M2 (μ-S)2 ] present a recurring motif in natural metalloproteins that is associated in a variety of biological processes, including reversible bond making and breaking, electron transfer, and cellular regulation
A phosphine coligand mimics the role of anionic donors present in natural sites that saturate metal coordination
The dominance of antiferromagnetic over ferromagnetic coupling of the high-spin iron ions [4] has been attributed to result from the covalent bonding along the Fe–sulfido–Fe linkages, rendering the mixed-valent S = 1/2 form [Fe(III)(μ-S)2 Fe(II)]+ energetically favorable [2,5]
Summary
Sulphur-bridged bimetallic structures of the general formula [M2 (μ-S)2 ] present a recurring motif in natural metalloproteins that is associated in a variety of biological processes, including reversible bond making and breaking, electron transfer, and cellular regulation. The prominence of [M2 (μ-S)2 ] sites in nature likely derives from the intriguing properties of the bond between metal and sulphur, be it inorganic sulfide or organic thiolate. The covalent character of an M–S bond varies sensitively with effective core charge and d-electron count of the metal. Fe containing bimetallic CuA [1,2] and 2Fe-ferredoxins [3] disclosed that it is the degree of covalent bonding that determines the mechanism and strength of electronic coupling of the metals in these archetypal [M2 (μ-S)2 ] structures [2].
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