“Cobalt tetracarbonyl hydride”的意思、由来-开放百科全书

Cobalt tetracarbonyl hydride is an organometallic compound with the formula HCo(CO)₄. It is a volatile, yellow liquid that forms a colorless vapor and has an intolerable odor.^[2] The compound readily decomposes upon melt and in absentia of high CO partial pressures forms Co₂(CO)₈. Despite operational challenges associated with its handling, the compound has received considerable attention for its ability to function as a catalyst in hydroformylation. In this respect, HCo(CO)₄ and related derivatives have received significant academic interest for their ability to mediate a variety of carbonylation (introduction of CO into inorganic compounds) reactions.

Structure and properties

HCo(CO)₄ adopts trigonal bipyrimidal structure with the equatorial CO ligands slightly bent out of the equatorial plane. The hydride ligand occupies one of the axial positions, thus the symmetry of the molecule is C_3v.^[9] The Co–CO and Co–H bond distances were determined by gas-phase electron diffraction to be 1.764 and 1.556 Å, respectively.^[3] Assuming the presence of a formal hydride ion, the oxidation state of cobalt in this compound is +1.

Unlike some other transition-metal hydrides complexes, HCo(CO)₄ is highly acidic, with a pK_a of 8.5.^[4] It readily undergoes substitution by tertiary phosphines and other Lewis-bases. For example, triphenylphosphine gives HCo(CO)₃PPh₃ and HCo(CO)₂(PPh₃)₂. These derivatives are more stable than HCo(CO)₄ and are used industrially to improve catalyst selectivity in hydroformylation.^[12] These derivatives are generally less acidic than HCo(CO)₄.^[4]

Preparation

Tetracarbonylhydrocobalt was first described by Hieber in the early 1930s.^[5] It was the second transition metal hydride to be discovered, after H₂Fe(CO)₄. It is prepared by reducing Co₂(CO)₈ with sodium amalgam or a similar reducing agent followed by acidification.^[6]

Since HCo(CO)₄ decomposes so readily, it is usually generated in situ by hydrogenation of Co₂(CO)₈.^[7]

The thermodynamic parameters for the equilibrium reaction were determined by infrared spectroscopy to be ΔH = 4.054 kcal mol⁻¹, ΔS = −3.067 cal mol⁻¹ K⁻¹.^[7]

Applications

Tetracarbonylhydridocobalt was the first transition metal hydride to be used in industry.^[8] In 1953 evidence was disclosed that it is the active catalyst for the conversion of alkenes, CO, and H₂ to aldehydes, a process known as hydroformylation (oxo reaction).^[9] Although the use of cobalt-based hydroformylation has since been largely superseded by rhodium-based catalysts, the world output of C₃–C₁₈ aldehydes produced by tetracarbonylhydrocobalt catalysis is about 100,000 tons/year, roughly 2% of the total.^[8]

References

1. ^¹²³⁴⁵⁶{{PGCH|0148}}
2. ^{{Cite book| last1 = Kerr | first1 = W. J.| year = 2001| chapter = Sodium Tetracarbonylcobaltate| title = Encyclopedia of Reagents for Organic Synthesis| doi = 10.1002/047084289X.rs105}}
3. ^{{Cite journal| doi = 10.1021/ja00461a011| title = Molecular structure of the gaseous metal carbonyl hydrides of manganese, iron, and cobalt| year = 1977| last1 = McNeill | first1 = E. A.| last2 = Scholer | first2 = F. R.| journal = Journal of the American Chemical Society| volume = 99| issue = 19| pages = 6243}}
4. ^¹{{Cite journal| doi = 10.1021/ja00269a022| pmid = 22175569| title = Kinetic and thermodynamic acidity of hydrido transition-metal complexes. 3. Thermodynamic acidity of common mononuclear carbonyl hydrides| year = 1986| last1 = Moore | first1 = E. J.| last2 = Sullivan | first2 = J. M.| last3 = Norton | first3 = J. R.| journal = Journal of the American Chemical Society| volume = 108| issue = 9| pages = 2257–2263}}
5. ^{{Cite journal| doi = 10.1002/cber.19320650709| title = Derivate des Kobalt- und Nickelcarbonyls (XVI. Mitteil. über Metallcarbonyle)| year = 1932| last1 = Hieber | first1 = W.| last2 = Mühlbauer | first2 = F.| last3 = Ehmann | first3 = E. A.| journal = Berichte der deutschen chemischen Gesellschaft (A and B Series)| volume = 65| issue = 7| pages = 1090}}
6. ^¹{{Cite book| last1 = Donaldson | first1 = J. D.| last2 = Beyersmann | first2 = D.| year = 2005| chapter = Cobalt and Cobalt Compounds| title = Ullmann's Encyclopedia of Industrial Chemistry| publisher = Wiley-VCH| doi = 10.1002/14356007.a07_281.pub2}}
7. ^¹²{{cite book|first1=M. |last1=Pfeffer |first2=M. |last2=Grellier |chapter=Cobalt Organometallics |title=Comprehensive Organometallic Chemistry III |date=2007 |publisher=Elsevier |doi=10.1016/B0-08-045047-4/00096-0}}
8. ^¹{{Cite book| last1 = Rittmeyer | first1 = P.| last2 = Wietelmann | first2 = U.| year = 2000| chapter = Hydrides| title = Ullmann's Encyclopedia of Industrial Chemistry| publisher = Wiley-VCH| doi = 10.1002/14356007.a13_199}}
9. ^{{cite journal|first1=I. |last1=Wender |first2=H. W. |last2=Sternberg |first3=M. |last3=Orchin |title=Evidence for Cobalt Hydrocarbonyl as the Hydroformylation Catalyst |journal=J. Am. Chem. Soc. |date=1953 |volume=75 |pages=3041–3042 |doi=10.1021/ja01108a528}}