Metal cluster compound
Metal cluster compounds are a molecular ion or neutral compound composed of three or more metals and featuring significant metal-metal interactions.
Transition metal carbonyl clusters
The development of metal carbonyl clusters such as Ni4 and Fe5 led quickly to the isolation of Fe29 and Fe312. Rundle and Dahl discovered that Mn210 featured an "unsupported" Mn-Mn bond, thereby verifying the ability of metals to bond to one another in molecules. In the 1970s, Paolo Chini demonstrated that very large clusters could be prepared from the platinum metals, one example being 2−. This area of cluster chemistry has benefited from single-crystal X-ray diffraction.Many metal carbonyl clusters contain ligands aside from CO. For example, the CO ligand can be replaced with myriad alternatives such as phosphines, isocyanides, alkenes, hydride, etc. Some carbonyl clusters contain two or more metals. Others contain carbon vertices. One example is the methylidyne-tricobalt cluster Methylidynetricobaltnonacarbonyl|. The above-mentioned cluster serves as an example of an overall zero-charged cluster. In addition, cationic rather than neutral organometallic trimolybdenum or tritungsten clusters are also known. The first representative of these ionic organometallic clusters is 2+.
Transition metal halide clusters
The halides of low-valent early metals often are clusters with extensive M-M bonding. The situation contrasts with the higher halides of these metals and virtually all halides of the late transition metals, where metal-halide bonding is replete.Transition metal halide clusters are prevalent for the heavier metals: Zr, Hf, Nb, Ta, Mo, W, and Re. For the earliest metals Zr and Hf, interstitial carbide ligands are also common. One example is Zr6CCl12. One structure type features six terminal halides and 12 edge-bridging halides. This motif is exemplified by tungsten chloride, 4−, Another common structure has six terminal halides and 8 bridging halides, e.g. Mo6Cl142−.
Image:EntryWithCollCode26094.png|right|200px|thumb|Structure of edge-capped octahedral clusters such as Ta6Cl184−.
Many of the early metal clusters can only be prepared when they incorporate interstitial atoms.
In terms of history, Linus Pauling showed that "MoCl2" consisted of Mo6 octahedra. F. Albert Cotton established that "ReCl3" in fact features subunits of the cluster Re3Cl9, which could be converted to a host of adducts without breaking the Re-Re bonds. Because this compound is diamagnetic and not paramagnetic the rhenium bonds are double bonds and not single bonds. In the solid state further bridging occurs between neighbours and when this compound is dissolved in hydrochloric acid a Re3Cl123− complex forms. An example of a tetranuclear complex is hexadecamethoxytetratungsten W412 with tungsten single bonds. A related group of clusters with the general formula MxMo6X8 such as PbMo6S8. These sulfido clusters are called Chevrel phases.
Fe-S clusters in biology
In the 1970s, ferredoxin was demonstrated to contain Fe4S4 clusters and later nitrogenase was shown to contain a distinctive MoFe7S9 active site. The Fe-S clusters mainly serve as redox cofactors, but some have a catalytic function. In the area of bioinorganic chemistry, a variety of Fe-S clusters have also been identified that have CO as ligands.Image:FdRedox.png|center|500px
File:FeMoco cluster.svg|thumb|right|200px|Structure of the FeMo cofactor showing the sites of binding to nitrogenase. The amino acids cysteine and histidine are indicated.
FeMoco, the active site of most nitrogenases, features a Fe7MoS9C cluster.