Dirhenium decacarbonyl explained

Dirhenium decacarbonyl is the inorganic compound with the chemical formula Re₂(CO)₁₀ . Commercially available, it is used as a starting point for the synthesis of many rhenium carbonyl complexes. It was first reported in 1941 by Walter Hieber, who prepared it by reductive carbonylation of rhenium.^[1] The compound consists of a pair of square pyramidal Re(CO)₅ units joined via a Re-Re bond, which produces a homoleptic carbonyl complex.^[2]

History

In the 1930s Robert Mond developed methods which used increased pressure and temperature to produce various forms of metal carbonyl . A prominent scientist of the twentieth century, Walter Hieber was crucial to the further development of specifically the dirhenium decacarbonyl. Initial efforts produced mononuclear metal complexes, but upon further evaluation, Hieber discovered that by using Re₂O₇ as a starting material with no solvent, a dirhenium complex could be achieved producing a Re-Re interaction.^[3]

Structure and properties

The crystal structure of Re₂(CO)₁₀ is relatively well known. The compound consists of a pair of square pyramidal Re(CO)₅ units linked by a Re-Re bond. There are two different conformations that can occur: staggered and eclipsed. The eclipsed conformation occurs about 30% of the time, producing a D_4h point group, but the staggered form, with point group D_4d, is more stable. The Re-Re bond length was experimentally found to be 3.04Å.^[4]

The Re atom exists in a slightly distorted octahedral configuration with the C axial-Re-C equatorial angle equal to 88°. The mean Re-C bond length of 2.01 Å is the same for the axial and equatorial positions. The mean C-O distance is 1.16 Å.^{[1] [5]}

This compound has a broad IR absorption band at 1800 cm⁻¹ region can be assigned to two components centered at 1780 and 1830 cm⁻¹, resulting from CO adsorption. The remaining nine CO groups in Re₂(CO)₁₀ give the complex IR absorption in the 1950–2150 cm⁻¹ region. Free Re₂(CO)₁₀ (point symmetry D_4d) has a CO stretch representation of 2A₁+E₂ + E₃+ 2B₂ +E₁, where 2B₂ + E₁ are IR active. For an axially perturbed (C_4v) Re₂(CO)₁₀ molecule, the CO stretch representation was found to be 2E+B₁+B₂+3A₁, where the IR active modes are 2E+3A₁.^[6]

Its identity can also be confirmed by mass spectrometry, using the isotopic pattern of rhenium (¹⁸⁵Re and ¹⁸⁷Re).^[7]

Synthesis

Dirhenium decacarbonyl may be obtained by reductive carbonylation of rhenium(VII) oxide (Re₂O₇) at 350 atm and 250 °C.^[3]

Re₂O₇ + 17 CO → Re₂(CO)₁₀ + 7 CO₂

It can also be prepared by the reaction of a methanol solution of sodium perrhenate and carbon monoxide at 230 °C and 115 atm.^[8]

Reactions

The carbonyl ligands may be displaced by other ligands such as phosphines and phosphites (denoted L).^{[7] [9]}

Re₂(CO)₁₀ + 2 L → Re₂(CO)₈L₂

This compound may also be "cracked" to mononuclear Re(I) carbonyl complexes by halogenation:^[10]

Re₂(CO)₁₀ + X₂ → 2 Re(CO)₅X (X = Cl, Br, I)

When bromine is used, bromopentacarbonylrhenium(I) is formed, which is an intermediate for many more rhenium complexes.^[7] This compound may also be hydrogenated to form various polyrhenium complexes, eventually giving elemental rhenium.^[11]

Re₂(CO)₁₀ → H₃Re₃(CO)₁₂ → H₅Re₄(CO)₁₂ → Re (metal)

In the presence of water, photolysis of Re₂(CO)₁₀ yields a hydroxide complex:^[12]

Re₂(CO)₁₀ → HRe(CO)₅ + Re₄(CO)₁₂(OH)₄

This reaction includes the cleavage of Re-Re bond and the synthesis of HRe(CO)₅, which can be used to prepare surface structures designed to incorporate isolated surface-bound Re carbonyl complexes.^[13]

Loss of a carbonyl ligand by photolysis generates a coordinatively unsaturated complex that undergoes oxidative addition of Si-H bonds, for example:

Re₂(CO)₁₀ + HSiCl₃* → (CO)₅ReHRe(CO)₄SiCl₃ + CO

Applications

Rhenium-based catalysis have been used in metathesis, reforming, hydrogenation and various hydrotreating processes such as hydrodesulfurization.^[14] Re₂(CO)₁₀ can be used to promote the silation of alcohols and prepare the silyl ethers, and its reaction:^[15]

RSiH₃ + R'OH → RH₂SiOR' + H₂.

See also

• Metal carbonyl

Notes and References

1. W. Hieber . H. Fuchs . Über Metallcarbonyle. XXXVIII. Über Rheniumpentacarbonyl . . 1941 . 248 . 3 . 256–268 . 10.1002/zaac.19412480304 . German.
2. Shiver and Atkins' Inorganic Chemistry 5th edition . F. Armstrong . J. Rourke . M. Hagerman . M. Weller . P. Atkins . T. Overton . 555 . 2010.
3. H. Werner. Organo-Transition Metal Chemistry: A personal View . limited. 2009 . 93.
4. M. Churchill . K. Amoh . H. Wasserman . Redetermination of the crystal structure of dimanganese decacarbonyl and determination of the crystal structure of dirhenium decacarbonyl. Revised values for the manganese-manganese and rhenium-rhenium bond lengths in dimanganese decacarbonyl and dirhenium decacarbonyl . . 1981 . 20 . 3 . 1609–1612. 10.1021/ic50219a056. dimanganese decacarbonyl .
5. N.IGapotchenko . Molecular structure of dirhenium decacarbonyl . . 1972 . 35 . 2 . 319–320 . 10.1016/S0022-328X(00)89806-X. etal.
6. . Vapour phase deposition and thermal decarbonylation of Re₂(CO)₁₀ on gamma-alumina: infrared studies. E. Escalona Platero . F.R. Peralta . C. Otero Areán . 34 . 1. 65–73. 1995 . 10.1007/BF00808323. 101025211.
7. . Mechanisms of dirhenium decacarbonyl substitution reactions: crossover experiments with dirhenium-185 decacarbonyl and dirhenium-187 decacarbonyl. A.M. Stolzenberg . E.L. Muetterties . 105 . 4 . 822–827. 1983 . 10.1021/ja00342a029.
8. Crocker. Lisa S.. Gould. George L.. Heinekey. D. Michael. 1988. Improved Synthesis of Carbonylrhenium. Journal of Organometallic Chemistry. 342. 2. 243–244. 10.1016/s0022-328x(00)99461-0.
9. . Sonochemistry of dimanganese decacarbonyl (Mn₂(CO)₁₀) and dirhenium decacarbonyl (Re₂(CO)₁₀). K.S. Suslick . P.F. Schubert . 105. 19 . 6042–6044. 1983 . 10.1021/ja00357a014.
10. Book: Pentacarbonylrhenium Halides . Steven P. Schmidt . William C. Trogler . Fred Basolo . 28 . 154–159 . 2007 . 10.1002/9780470132593.ch42. Inorganic Syntheses . 9780470132593 .
11. Mechanism of particle formation in decomposing Re₂(CO)₁₀ on NaY and NaHY zeolites: effect of prereduced Pt clusters in the supercages. Journal of Molecular Catalysis. C. Dossi, J. Schaefer, W. M. H. Sachtler. 52. 1 . 193–209 . 1989 . 10.1016/0304-5102(89)80089-6.
12. . Photochemical reactions of dirhenium decacarbonyl with water. D. R. Gard . T. L. Brown . 104 . 23 . 6340–6347. 1982 . 10.1021/ja00387a031.
13. . Surface catalytic sites prepared from [HRe(CO)₅] and [H₃Re₃(CO)₁₂]: mononuclear, trinuclear, and metallic rhenium catalysts supported on magnesia. P. S. Kirlin . etal . 94 . 92 . 8439–8450. 1990 . 10.1021/j100385a017. 1874/5964. 55214603.
14. . Controlled gas-phase preparation and HDS activity of Re₂(CO)₁₀ alumina catalysts. R. Jarkko . A.P. Tapani . 65. 4 . 175–180. 2000 . 10.1023/A:1019006413873. 96952765.
15. . Mechanism and utility of the dirhenium decacarbonyl catalyzed formation of silyl ethers. D.H.R.Barton, M.J. Kelly. 33. 35 . 5041–5044. 1992 . 10.1002/chin.199302225.