Disulfidobis(tricarbonyliron), or Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub>, is an organometallic molecule used as a precursor in the synthesis of iron-sulfur compounds. Popularized as a synthetic building block by Dietmar Seyferth, Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> is commonly used to make mimics of the H-cluster in [FeFe]-hydrogenase. Much of the reactivity of Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> proceeds through its sulfur-centered dianion, [Fe<sub>2</sub>(ü-S)<sub>2</sub>(CO)<sub>2</sub>]<sup>2-</sup>.
The synthesis of Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> was first reported in 1958 from iron pentacarbonyl and sodium polysulfide.
The vibrant red, air-stable product is formed alongside Fe<sub>3</sub>S<sub>2</sub>(CO)<sub>9</sub>, and can be separated by sublimation. The molecule has an Fe<sub>2</sub>S<sub>2</sub> core with a distorted tetrahedron shape. The compound sublimes at 40 ðC, melts at 46.5 ðC, and decomposes at 70 ðC. Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> has three peaks in its infrared spectrum corresponding to three distinct carbonyl stretching frequencies, indicating that the carbonyl ligands are inequivalent. There are multiple peaks in the ultraviolet-visible spectrum, with a peak at 449 nm corresponding to a metal-to-ligand charge transfer band. The dianion [Fe<sub>2</sub>(ü-S)<sub>2</sub>(CO)<sub>2</sub>]<sup>2-</sup> is most easily prepared by reduction of Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> with LiBEt<sub>3</sub>H, also known as Super-Hydride.
In the neutral cluster, the sulfur atoms are bound to each other, forming a disulfide ligand. In the sulfur-centered dianion, the sulfur-sulfur bond is broken, forming two anionic sulfide ligands. Therefore, the bridging unit in the neutral cluster is a S<sub>2</sub><sup>2-</sup> ligand, while the bridging unit in the dianion is a single S<sup>2-</sup> ion.
Studies of the coupling between iron-57 and carbon-13 atoms in carbon-13 NMR spectroscopy indicate rapid intermolecular exchange of carbonyl ligands between clusters.
The crystal structure of Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> was first reported in 1965. The Fe<sub>2</sub>S<sub>2</sub> core forms a tetrahedron, though calculations show that the 'butterfly' structure with a broken SâÂÂS bond and diradical character is not substantially higher in energy. Seeking to explain the compound's diamagnetism, both an ironâÂÂiron and a sulfurâÂÂsulfur bond were proposed. In early works, to comport with a d<sup>2</sup>sp<sup>3</sup> hybrid orbital interpretation of the bonding in octahedral metal complexes, the metalâÂÂmetal bond was proposed to be "bent." However, the directionality of this bond faced some controversy. With the advent of computational chemistry programs such as density functional theory (DFT) and the quantum theory of atoms in molecules (QTAIM), this bond and its topology have been thoroughly investigated, and some calculations support a nonlinear ironâÂÂiron bond. However, these calculations indicate that the bond angle is likely closer to 15ð than the 130ð originally proposed.
Computational work indicates that the highest occupied molecular orbital (HOMO) of the compound is FeâÂÂFe bonding in nature and substantially delocalized, while the lowest unoccupied molecular orbital (LUMO) is a localized SâÂÂS sigma bond. Much of the sulfur-centered reactivity of this compound can thus be understood in terms of frontier orbital theory.
The Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> molecule is a useful synthetic precursor to a variety of FeâÂÂS multinuclear compounds. Reactivity frequently begins with reductive cleavage of the sulfurâÂÂsulfur bond to [Fe<sub>2</sub>(ü-S)<sub>2</sub>(CO)<sub>2</sub>]<sup>2-</sup>, though syntheses directly from the neutral cluster are also known.
The first step in many reactions with Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> is reduction to the dianion, which is easily performed with lithium triethylborohydride.
The resulting dianion can then be reacted with a dihaloalkane to form a cyclic alkane thiolate. Cyclic alkane thiolates have been used as precursors to active catalysts for electrocatalytic hydrogen evolution, which can be considered a model reaction for the all-iron hydrogenase.
The dianion can also be treated with two different haloalkanes to form an asymmetric alkylated species.
In addition to electrophilic organic reagents, [Fe<sub>2</sub>(ü-S)<sub>2</sub>(CO)<sub>2</sub>]<sup>2-</sup> can be treated with inorganic or organometallic reagents to insert a variety of heterometals.
The neutral compound is electrophilic at the sulfurâÂÂsulfur bond, meaning that it can be treated with carbanionic reagents (for example, Grignard or organolithium reagents). Use of carbanionic reagents (RM) allows for asymmetric functionalization of the two sulfur atoms.
Reactivity mimicking that of the dianion can be achieved directly from the neutral species through photochemistry. Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> absorbs light at 450 nm, corresponding to a metal-to-ligand charge transfer (MLCT) from the Fe-centered HOMO to the S-centered LUMO. As the HOMO is bonding with respect to the FeâÂÂFe bond, and the LUMO is antibonding with respect to the SâÂÂS bond, promotion of an electron from the HOMO to the LUMO weakens both bonds. This can be treated as reduction of the sulfur bridge by the iron core.
Temporary sulfur-centered dianion character allows the formally neutral molecule to perform oxidative addition reactions with organic small molecules:
Synthetic models of the H-cluster of the all-iron hydrogenase have been synthesized. Treating the dianion [Fe<sub>2</sub>(ü-S)<sub>2</sub>(CO)<sub>2</sub>]<sup>2-</sup> with trifluoroacetic acid produces the dithiol derivative Fe<sub>2</sub>(ü-SH)<sub>2</sub>(CO)<sub>6</sub>, which can then be reacted with ammonium carbonate in paraformaldehyde to form a structural model of the H-cluster.
In addition to structural mimics of the H-cluster, work has been done to model the reactivity of the all-Fe hydrogenase. The cyclic propyl thiolate cluster derived from Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> (see above) acts as a precatalyst, and when treated with acid in an electrolysis cell, hydrogen gas is produced. As a result, this system can be used as a model to better understand the mechanism of hydrogen production in the all-Fe hydrogenase.
The synthesis of Fe<sub>2</sub>(ü-S<sub>2</sub>)(CO)<sub>6</sub> has been proposed as an educational experiment in upper-level undergraduate inorganic laboratory courses.