Acetylacetone

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Acetylacetone
IUPAC name Pentane-2,4-dione
Molecular formula C5H8O2
Molar mass 100.13 g/mol
Density 0.98 g/ml
Solubility 16 g/100 mL
Melting point

−23 °C

Boiling point

140 °C

Hazards
EU classification {{{value}}}
R-phrases R10, R22
S-phrases (S2), S21, S23, S24/25
Flash point {{{value}}}
Explosive limits 2.4–11.6%
Except where noted otherwise, data are given for
materials in their standard state
(at 25 °C, 100 kPa)

Infobox disclaimer and references


Acetylacetone is an organic compound with molecular formula C5H8O2. This diketone is formally named 2,4-pentanedione, although as discussed below, this name does not properly describe the predominant structure. It is a precursor to common bidentate ligand and a building block for the synthesis of heterocyclic compounds.

Properties

The keto and enol forms of acetylacetone coexist in solution; these forms are tautomers. The C2v symmetry for the enol form displayed on the right in scheme 1 has been verified by many methods including microwave spectroscopy.[1] Hydrogen bonding in the enol reduces the steric repulsion between the cabonyl groups. In the gas phase K is 11.7. The equilibrium constant tends to be high in nonpolar solvents: cyclohexane is 42, toluene is 10, THF 7.2, dimethylsulfoxide (K=2), and water (K=0.23).[2]

Scheme 1. Tautomerism of 2,4-pentanedione

Preparation

Two common procedures are used for synthesizing acetylacetone. Acetone and acetic anhydride react upon the addition of BF3 catalyst.

(CH3CO)2O + CH3C(O)CH3 → CH3C(O)CH2C(O)CH3

The second synthesis involves the base-catalyzed condensation of acetone and ethyl acetate, followed by acidification

NaOEt + EtO2CCH3 + CH3C(O)CH3 → NaCH3C(O)CHC(O)CH3 + 2 EtOH
NaCH3C(O)CHC(O)CH3 + HCl → CH3C(O)CH2C(O)CH3 + NaCl

Because of the ease of these syntheses, many analogues of acetylacetonates are known. Some examples include C6H5C(O)CH2C(O)C6H5 (dbaH) and (CH3)3CC(O)CH2C(O)CC(CH3)3. Hexafluoroacetylacetonate is also widely used to generate volatile metal complexes.

Acetylacetonate "anion"

C5H7O2, is the conjugate base of 2,4-pentanedione. In reality, the free ion does not exist in solution, but is bound to the corresponding cation, such as Na+. In practice, the existence of the free anion, commonly abbreviated acac, is a useful model.

Coordination chemistry

The acetylacetonate anion forms complexes with many transition metal ions wherein both oxygen atoms bind to the metal to form a six-membered chelate ring. Some examples include: Mn(acac)3,[3] VO(acac)2, Fe(acac)3, and Co(acac)3. Any complex of the form M(acac)3 is chiral (has a non-superimposable mirror image). Additionally, M(acac)3 complexes can be reduced electrochemically, with the reduction rate being dependent on the solvent and the metal center.[4] Bis- and tris complexes of the type M(acac)2 and M(acac)3 are typically soluble in organic solvents, in contrast to the related metal halides. Because of this properties, these complexes are widely used as catalyst precursors and reagents. Important applications include their use as NMR "shift reagents" and as catalysts for organic synthesis, and precursors to industrial hydroformylation catalysts.

C5H7O2 in some cases also binds to metals through the central carbon atom; this bonding mode is more common for the third-row transition metals such as platinum(II) and iridium(III).

Scheme 1. Chirality of M(acac)3

Illustrative metal acetylacetonates

Chromium (III) acetylacetonate

Cr(acac)3 (CAS registry number 21679-31-2) is used as a spin relaxation agent to improve the sensitivity in quantitative Carbon-13 NMR spectroscopy.[5]

Copper(II) acetylacetonate

Cu(acac)2, prepared by treating acetylacetone with aqueous Cu(NH3)42+ and is available commercially, catalyzes coupling and carbene transfer reactions.

Scheme 1. Structure of copper(II) acetylacetonate

Copper(I) acetylacetonate

Unlike the copper(II) chelate, copper(I) acetylacetonate is an air sensitive oligomeric species. It is employed to catalyze Michael additions.[6]

Manganese(III) acetylacetonate

File:Lambda-tris(acetylacetonato)manganese(III)-3D-balls.png
Ball-and-stick model of Λ-Mn(acac)3, with Jahn-Teller tetragonal elongation

Mn(acac)3, a one-electron oxidant, is used for coupling phenols.[3] It is prepared by the direct reaction of acetylacetone and potassium permanganate. In terms of electronic structure, Mn(acac)3 is high spin. Its distorted octahedral structure reflects geometric distortions due to the Jahn-Teller effect. The two most common structures for this complex include one with tetrahedral elongation and one with tetragonal compression. For the elongation, two Mn-O bonds are 2.12 Å while the other four are 1.93 Å. For the compression, two Mn-O bonds are 1.95 and the other four are 2.00 Å. The effects of the tetrahedral elongation are noticeably more significant than the effects of the tetragonal compression.[7]

Scheme 1. Structure of manganese(III) acetylacetonate

Nickel(II) acetylacetonate

"Nickel acac" is not Ni(acac)2 but the trimer [Ni(acac)2]3. This emerald green solid, which is benzene soluble, is widely employed in the preparation of Ni(O) complexes. Upon exposure to the atmosphere, [Ni(acac)2]3 converts to the chalky green monomeric hydrate.

C-bonded acetylacetonates

C5H7O2 in some cases also binds to metals through the central carbon atom (C3); this bonding mode is more common for the third-row transition metals such as platinum(II) and iridium(III). The complexes Ir(acac)3 and corresponding Lewis-base adducts Ir(acac)3L (L = an amine) contain one carbon-bonded acac ligand. The IR spectra of O-bonded acetylacetonates are characterized by relatively low-energy νCO bands of 1535 cm−1, whereas in carbon-bonded acetylacetonates, the carbonyl vibration occurs closer to the normal range for ketonic C=O, i.e. 1655 cm−1.

Other reactions of acetylacetone

  • Deprotonations: Very strong bases will doubly deprotonate acetylacetone, starting at C3 but also at C1. The resulting species can then be alkylated at C-1.
  • Precursor to heterocycles: Acetylacetone is a versatile precursor to heterocycles. Hydrazine reacts to produce pyrazoles. Urea gives pyrimidines.
  • Precursor to related imino ligands: Acetylacetone condenses with amines to give, successively, the mono- and the di-diketimines wherein the O atoms in acetylacetone are replaced by NR (R = aryl, alkyl).
  • Enzymatic breakdown: The enzyme acetylacetone dioxygenase cleave the carbon-carbon bond of acetyacetone, producing acetate and 2-oxopropanal. The enzyme is Fe(II)-dependent, but it has been proven to bind to zinc as well. Acetylacetone degradation has been characterized in the bacterium Acinetobacter johnsonii.[8]
C5H8O2 + O2 → C2H4O2 + C3H4O2
  • Arylation: Acetylacetonate displaced halides from certain halo-substituted benzoic acid. This reaction is copper-catalyzed.
2-BrC6H4CO2H + NaC5H7O2 → 2-(CH3CO)2HC)-C6H4CO2H + NaBr

References

  1. W. Caminati, J.-U. Grabow (2006). "The C2v Structure of Enolic Acetylacetone". Journal of the American Chemical Society. 128 (3): 854–857. doi:10.1021/ja055333g.
  2. Solvents and Solvent Effects in Organic Chemistry, Christian Reichardt Wiley-VCH; 3 edition 2003 ISBN 3-527-30618-8
  3. 3.0 3.1 B. B. Snider, "Manganese(III) Acetylacetonate" in Encyclopedia of Reagents for Organic Synthesis (Ed: L. Paquette) 2004, J. Wiley & Sons, New York. doi:10.1002/047084289
  4. W. Fawcett, M. Opallo (1992). "Kinetic parameters for heterogeneous electron transfer to tris(acetylacetonato)manganese(III) and tris(acetylacetonato)iron(III) in aproptic solvents". Journal of Electroanalytical Chemistry. 331: 815–830. doi:10.1016/0022-0728(92)85008-Q.
  5. Caytan, Elsa; Remaud, Gerald S.; Tenailleau, Eve; Akoka, Serge (2007), "Precise and accurate quantitative 13C NMR with reduced experimental time", Talanta, 71 (3): 1016–1021
  6. E. J. Parish, S. Li "Copper(I) Acetylacetonate" in Encyclopedia of Reagents for Organic Synthesis (Ed: L. Paquette) 2004, J. Wiley & Sons, New York. doi:10.1002/047084289X.rc203
  7. Straganz, G.D., Glieder, A., Brecker, L., Ribbons, D.W. and Steiner, W. "Acetylacetone-Cleaving Enzyme Dke1: A Novel C-C-Bond-Cleaving Enzyme." Biochem. J. 369 (2003) 573-581 doi:10.1042/BJ20021047

Further reading

  • Bennett, M. A.; Heath, G. A.; Hockless, D. C. R.; Kovacik, I.; Willis, A. C. "Alkene Complexes of Divalent and Trivalent Ruthenium Stabilized by Chelation. Dependence of Coordinated Alkene Orientation on Metal Oxidation State" Journal of the American Chemical Society 1998: 120 (5) 932-941. doi:10.1021/ja973282k
  • Albrecht, M. Schmid, S.; deGroot, M.; Weis, P.; Fröhlich, R. "Self-assembly of an Unpolar Enantiomerically Pure Helicate-type Metalla-cryptand" Chemical Communications 2003: 2526–2527. doi:10.1039/b309026d
  • Charles, R. G., "Acetylacetonate manganese (III)" Inorganic Synthesis, 1963, 7, 183-184.
  • Richert, S. A., Tsang, P. K. S., Sawyer, D. T., "Ligand-centered redox processes for manganese, iron and cobalt, MnL3, FeL3, and CoL3, complexes (L = acetylacetonate, 8-quinolinate, picolinate, 2,2'-bipyridyl, 1,10-phenanthroline) and for their tetrakis(2,6-dichlorophenyl)porphinato complexes[M(Por)]"Inorganic Chemistry, 1989, 28, 2471-2475. doi:10.1021/ic00311a044
  • Wong-Foy, A. G.; Bhalla, G.; Liu, X. Y.; Periana, R. A.. "Alkane C-H Activation and Catalysis by an O-Donor Ligated Iridium Complex." Journal of the American Chemical Society, 2003: 125 (47) 14292-14293. doi:10.1021/ja037849a
  • Tenn, W. J., III; Young, K. J. H.; Bhalla, G.; Oxgaard. J.; Goddard, W. A., III; Periana, R. A. "CH Activation with an O-Donor Iridium-Methoxo Complex." Journal of the American Chemical Society, 2005: 127 (41) 14172-14173. doi:10.1021/ja051497l
  • N. Barta, "Bis(acetylacetonato)zinc(II)" in Encyclopedia of Reagents for Organic Synthesis (Ed: L. Paquette) 2004, J. Wiley & Sons, New York. doi:10.1002/047084289X.rb097

External links

de:Acetylaceton#Acetylacetonat it:Acetilacetone lv:Acetilacetons



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