Triiron dodecacarbonyl

Triiron dodecacarbonyl is the organoiron compound with the formula Fe₃₁₂. It is a dark green solid that sublimes under vacuum. It is soluble in nonpolar organic solvents to give intensely green solutions. Most low-nuclearity clusters are pale yellow or orange. Hot solutions of Fe₃₁₂ decompose to an iron mirror, which can be pyrophoric in air. The solid decomposes slowly in air, and thus samples are typically stored cold under an inert atmosphere. It is a more reactive source of iron than iron pentacarbonyl.

Synthesis

It was one of the first metal carbonyl clusters synthesized. It was occasionally obtained from the thermolysis of Fe(CO)₅:
Traces of the compound are easily detected because of its characteristic deep green colour. UV-photolysis of Fe₅ produces Fe₂(CO)₉, not Fe₃₁₂.
The usual synthesis of Fe₃₁₂ starts with the reaction of Fe₅ with base:
followed by protonation of the resulting hydrido cluster with acid:
The original synthesis by Walter Hieber et al. entailed the oxidation of H₂Fe₄ with manganese dioxide. The cluster was originally formulated incorrectly as "Fe₄".

Structure

image:Fe3inC6Me3H3.jpg|thumb|left|140px|Saturated solution of Fe₃₁₂ in mesitylene.
Elucidation of the structure of Fe₃₁₂ proved to be challenging because the CO ligands are disordered in the crystals. Early evidence for its distinctive C_2v structure came from Mössbauer spectroscopic measurements that revealed two quadrupole doublets with similar isomer shifts but different ₁₂ consists of a triangle of iron atoms surrounded by 12 CO ligands. Ten of the CO ligands are terminal and two span an Fe---Fe edge, resulting in C_2v point group symmetry. By contrast, Ru₃(CO)₁₂ and Os₃(CO)₁₂ adopt D_3h-symmetric structures, wherein all 12 CO ligands are terminally bound to the metals. In solution Fe₃₁₂ is fluxional, resulting in equivalencing all 12 CO groups on the ¹³C NMR timescale.
The anion ⁻ is structurally related to Fe₃₁₂, with the hydride replacing one bridging CO ligand. The bonding in the Fe-H-Fe subunit is described using concepts developed for diborane.

Reactions

Solutions of Fe₃₁₂ reacts with triphenylphosphine to give (triphenylphosphine)iron tetracarbonyl.
Heating Fe₃₁₂ gives a low yield of the carbido cluster Fe₅₁₅C. Such reactions proceed via disproportionation of CO to give CO₂ and carbon.
Fe₃₁₂ forms "ferroles" upon reaction with heterocycles such as thiophenes.
Fe₃₁₂ reacts with thiols and disulfides to give thiolate-bridged complexes, such as methylthioirontricarbonyl dimer:

Safety

Fe₃₁₂ is hazardous as a source of carbon monoxide. Solid samples, especially when finely divided, and residues from reactions can be pyrophoric, which can ignite the organic solvents used for such reactions.