Metal acetylacetonates

Metal acetylacetonates are coordination complexes derived from the acetylacetonate anion (CH
3
COCHCOCH
3
) and metal ions, usually transition metals. The bidentate ligand acetylacetonate is often abbreviated acac. Typically both oxygen atoms bind to the metal to form a six-membered chelate ring. The simplest complexes have the formula M(acac)3 and M(acac)2. Mixed-ligand complexes, e.g. VO(acac)2, are also numerous. Variations of acetylacetonate have also been developed with myriad substituents in place of methyl (RCOCHCOR).[1] Many such complexes are soluble in organic solvents, in contrast to the related metal halides. Because of these properties, acac complexes are sometimes used as catalyst precursors and reagents. Applications include their use as NMR "shift reagents" and as catalysts for organic synthesis, and precursors to industrial hydroformylation catalysts. C
5
H
7
O
2
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).

Synthesis

The usual synthesis involves treatment of a metal salt with acetylacetone, acacH:[2]

Mz+ + z Hacac ⇌ M(acac)z + z H+

Addition of base assists the removal of a proton from acetylacetone and shifts the equilibrium in favour of the complex. Both oxygen centres bind to the metal to form a six-membered chelate ring. In some cases the chelate effect is so strong that no added base is needed to form the complex. Some complexes are prepared by metathesis using Tl(acac).

Structure and bonding

In the majority of its complexes acac forms six-membered C3O2M chelate rings.[3] The M(acac) ring is planar with a symmetry plane bisecting the ring.

The acacM ring generally exhibits aromatic character, consistent with delocalized bonding in the monoanionic C3O2 portion. Consistent with this scenario, in some complexes, the acac ligand is susceptible to electrophilic substitution, akin to electrophilic aromatic substitution (in this equation Me = CH3):[4]

Co(O2C3Me2H)3 + 3 NO2+ → Co(O2C3Me2NO2)3 + 3 H+

In terms of electron counting, neutral bidentate O,O-bonded acac ligand is an "L-X ligand", i.e. a combination of a Lewis base (L) and a pseudohalide (X).

An exception to the classical description presented above, the bis(pyridine) adduct of chromium(II) acetylacetonate features noninnocent acac2- ligand.[5]

Classification by triad

Titanium triad

Treatment of TiCl4 with acetylacetone gives TiCl2(acac)2, a red-coloured, octahedral complex with C2 symmetry:

TiCl4 + 2 Hacac → TiCl2(acac)2 + 2 HCl

This reaction requires no base. Under atmospheric conditions the dibromo complex is easily hydrolyzed (1 hr), whereas the dichloro and difluoro complexes are not easily hydrolyzed (1-3 days). The complex TiCl2(acac)2 is fluxional in solution, the NMR spectrum exhibiting a single methyl resonance at room temperature.[6]

Unlike Ti(IV), both Zr(IV) and Hf(IV) bind four bidentate acetylacetonates, reflecting the larger radius of these metals. Hafnium acetylacetonate and zirconium acetylacetonate adopt square antiprismatic structures.

Regarding acetylacetonates of titanium(III), Ti(acac)3 is well studied. This blue-colored compound forms from titanium trichloride and acetylacetone.[3]

Vanadium triad

A ball-and-stick model of VO(acac)2

Vanadyl acetylacetonate is a blue complex with the formula V(O)(acac)2. This complex features the vanadyl(IV) group, and many related compounds are known. The molecule is square pyramidal, with idealized C2v symmetry. The complex catalyzes epoxidation of allylic alcohols by peroxides. Vanadium(III) acetylacetonate is a dark-brown solid. Vanadium β-diketonate complexes are used as precatalysts in the commercial production of ethylene-propylene-diene elastomers (EPDM). They are often evaluated for other applications related to redox flow batteries, diabetes and enhancing the activity of insulin, and as precursors to inorganic materials by CVD.[7]

Chromium triad

Chromium(III) acetylacetonate, Cr(acac)3, is a typical octahedral complex containing three acac ligands. Like most such compounds, it is highly soluble in nonpolar organic solvents. This particular complex, which has a three unpaired electrons, is used as a spin relaxation agent to improve the sensitivity in quantitative carbon-13 NMR spectroscopy.[8] Chromium(II) acetylacetonate is a highly oxygen-sensitive, light brown compound. The complex adopts a square planar structure, weakly associated into stacks in the solid state. It is isomorphous with Pd(acac)2 and Cu(acac)2.[9] Mo(acac)3, a purple, air sensitive complex, is prepared by salt metathesis from hexachloromolybdate.[10][11]

Manganese triad

Ball-and-stick model of Δ-Mn(acac)3, with Jahn–Teller tetragonal elongation

Mn(acac)3 has been prepared by the comproportionation of the manganese(II) compound Mn(acac)2 with potassium permanganate in the presence of additional acetylacetone.[12] Alternatively the direct reaction of acetylacetone with potassium permanganate.[13] 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 tetragonal 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 Å and the other four are 2.00 Å. The effects of the tetragonal elongation are noticeably more significant than the effects of the tetragonal compression.[14]

Scheme 1. Structure of manganese(III) acetylacetonate

In organic chemistry, Mn(acac)3 has been used as a one-electron oxidant for coupling phenols.[15]

The electron transfer rates for Mn(acac)3 have been evaluated.[16]-

Mn(acac)2 is a tan solid obtained by vacuum drying the yellow dihydrate Mn(acac)2(H2O)2.[17]

Iron triad

Iron(III) acetylacetonate, Fe(acac)3, is a red high-spin complex that is highly soluble in organic solvents. It is a high-spin complex with five unpaired electrons. It has occasionally been investigated as a catalyst precursor.[18] Fe(acac)3 has been partially resolved into its Δ and Λ isomers.[19] The ferrous complex Fe(acac)2 is oligomeric.

Like iron, Ru(III) forms a stable tris(acetylacetonate). Reduction of this Ru(III) derivative in the presence of other ligands affords mixed ligand complexes, e.g. Ru(acac)2(alkene)2.[20]

Cobalt triad

Rh(acac)(CO)2 showing the "stacking" of the individual planar units through Rh---Rh interactions.

Tris(acetylacetonato)cobalt(III), Co(acac)3, is low-spin, diamagnetic complex. Like other compounds of the type M(acac)3, this complex is chiral (has a non-superimposable mirror image).[19]

Scheme 2. Chirality of M(acac)3

The synthesis of Co(acac)3 involves the use of an oxidant since the cobalt precursors are divalent:

2 CoCO3 + 6 Hacac + H2O2 → 2 Co(acac)3 + 4 H2O + 2 CO2

The complex "Co(acac)2", like the nickel complex with analogous stoichiometry, is typically isolated with two additional ligands, i.e. octahedral Co(acac)2L2. The anhydrous form exists as the tetramer [Co(acac)2]4. Like the trimeric nickel complex, this tetramer shows ferromagnetic interactions at low temperatures.[21]

Ir(acac)3 and Rh(acac)3 are known. A second linkage isomer of the iridium complex is known, trans-Ir(acac)2(CH(COMe)2)(H2O). This C-bonded derivative is a precursor to homogeneous catalysts for C–H activation and related chemistries.[22][23][24][25]

Two well-studied acetylacetonates of rhodium(I) and iridium(I) are Rh(acac)(CO)2 and Ir(acac)(CO)2. These complexes are square-planar, with C2v symmetry.

Nickel triad

Stick model of [Ni(acac)2]3

Nickel(II) bis(acetylacetonate) exists as the trimetallic complex [Ni(acac)2]3. Bulky beta-diketonates give red, monomeric, square-planar complexes.[26] Nickel(II) bis(acetylacetonate) reacts with water to give the octahedral[27] adduct [Ni(acac)2(H2O)2], a chalky green solid.

In contrast to the complicated magnetism and structures of Ni(acac)2, platinum(II) bis(acetylacetonate) and palladium(II) bis(acetylacetonate) are diamagnetic monometallic species.

Copper triad

Cu(acac)2 is prepared by treating acetylacetone with aqueous Cu(NH
3
)2+
4
. It is available commercially, catalyzes coupling and carbene transfer reactions.

Unlike the copper(II) derivative, copper(I) acetylacetonate is an air-sensitive oligomeric species. It is employed to catalyze Michael additions.[28]

Zinc triad

The monoaquo complex Zn(acac)2H2O (m.p. 138–140 °C) is pentacoordinate, adopting a square pyramidal structure.[29] The complex is of some use in organic synthesis.[30] Dehydration of this species gives the hygroscopic anhydrous derivative (m.p. 127 °C).[31] This more volatile derivative has been used as a precursor to films of ZnO.

Acetylacetonates of the other elements

Colourless aluminium acetylacetonate (Al(acac)3) is structurally similar to other tris complexes, e.g. [Fe(acac)3]. The trisacetylacetonates of the lanthanides often adopt coordination numbers above 8.

Variants of acac

Many variants of acetylacetonates are well developed. Hexafluoroacetylacetonates and trifluoroacetylacetonates form complexes that are often structurally related to regular acetylacetonates, but are more Lewis acidic and more volatile. The complex Eufod, Eu(OCC(CH3)3CHCOC3F7)3, features an elaborate partially fluorinated ligand. This complex is a Lewis acid, forming adducts with a variety of hard bases.

One or both oxygen centers in acetylacetonate can be replaced by RN groups, giving rise to Nacac and Nacnac ligands.

C-bonded acetylacetonates

C
5
H
7
O
2
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.

References

  1. ^ Albrecht, M.; Schmid, S.; De Groot, M.; Weis, P.; Fröhlich, R. (2003). "Self-assembly of an Unpolar Enantiomerically Pure Helicate-type Metalla-cryptand". Chem. Comm. 2003 (20): 2526–2527. doi:10.1039/b309026d. PMID 14594263.
  2. ^ R. C. Mehrotra; R. Bohra; D. P. Gaur (1978). Metal ß-Diketones and Allied Derivatives. Academic Press. ISBN 0-12-488150-5.
  3. ^ a b Arslan, Evrim; Lalancette, Roger A.; Bernal, Ivan (2017). "An Historic and Scientific Study of the Properties of Metal(III) Tris-acetylacetonates". Structural Chemistry. 28: 201–212. doi:10.1007/s11224-016-0864-0. S2CID 99668641.
  4. ^ Shalhoub, George M. (1980). "Co(acac)3 Synthesis, Reactions, and Spectra: An Experiment for General Chemistry". Journal of Chemical Education. 57 (7): 525. Bibcode:1980JChEd..57..525S. doi:10.1021/ed057p525.
  5. ^ Vinum, Morten Gotthold; Voigt, Laura; Hansen, Steen H.; Bell, Colby; Clark, Kensha Marie; Larsen, René Wugt; Pedersen, Kasper S. (2020). "Ligand field-actuated redox-activity of acetylacetonate". Chemical Science. 11 (31): 8267–8272. doi:10.1039/d0sc01836h. PMC 8163028. PMID 34094180.
  6. ^ Wilkie, C. A.; Lin, G.; Haworth, D. T. (1979). "Cis -[Dihalobis(2,4-Pentaedionato)Titanium(IV)] Complexes". Inorganic Syntheses. Vol. 19. pp. 145–148. doi:10.1002/9780470132500.ch33. ISBN 978-0-470-13250-0. {{cite book}}: |journal= ignored (help)
  7. ^ V. D. Makhaev; L. A. Petrova (2017). "Mechanochemical synthesis of vanadium(III) β-diketonates". Zhurnal Obshchei Khimii (Russian Journal of General Chemistry). 87 (6): 1105–1109. doi:10.1134/s1070363217060019. S2CID 103887631.
  8. ^ 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. doi:10.1016/j.talanta.2006.05.075. PMID 19071407.
  9. ^ Cotton, F. A.; Rice, C. E.; Rice, G. W. (1977). "The Crystal and Molecular Structures of Bis(2,4-pentanedionato)chromium". Inorg. Chim. Acta. 24: 231–234. doi:10.1016/S0020-1693(00)93880-5.
  10. ^ Larson, Melvin L.; Moore, Fred W.; Waller, James; Bryant, Burl E. (1966). "Tris(2,4-pentanedionato)molybdenum (III)". Inorganic Syntheses. Vol. 8. pp. 153–156. doi:10.1002/9780470132395.ch40. ISBN 978-0-470-13167-1.
  11. ^ Ledneva, A. Yu.; Artemkina, S. B.; Piryazev, D. A.; Fedorov, V. E. (2015). "Structure and Thermal Properties of the Molybdenum Complex Mo(acac)3". Journal of Structural Chemistry. 56 (5): 1021–1023. doi:10.1134/S0022476615050315.
  12. ^ Charles, R. G. (1963). "Acetylacetonato manganese(III)". Inorganic Syntheses Vol 7. Vol. 7. pp. 183–184. doi:10.1002/9780470132388.ch49. ISBN 978-0-470-13238-8. {{cite book}}: |journal= ignored (help)
  13. ^ Girolami, G.; Rauchfuss, T.; Angelici, R. Synthesis and Technique in Inorganic Chemistry, 3rd ed.; University Science Books: Sausalito, CA, 1999; pp. 85-92. ISBN 0-935702-48-2
  14. ^ Cotton, F. Albert; Wilkinson, Geoffrey; Murillo, Carlos A.; Bochmann, Manfred (1999), Advanced Inorganic Chemistry (6th ed.), New York: Wiley-Interscience, ISBN 0-471-19957-5
  15. ^ Snider, B. B. (2001). "Manganese(III) Acetylacetonate". In Paquette, L. (ed.). Encyclopedia of Reagents for Organic Synthesis. New York, NY: J. Wiley & Sons. doi:10.1002/047084289X.rm022. ISBN 0-471-93623-5.
  16. ^ Fawcett, W.; Opallo, M. (1992). "Kinetic parameters for heterogeneous electron transfer to tris(acetylacetonato)manganese(III) and tris(acetylacetonato)iron(III) in aprotic solvents". Journal of Electroanalytical Chemistry. 331 (1–2): 815–830. doi:10.1016/0022-0728(92)85008-Q.
  17. ^ Charles, Robert G. (1960). "Manganese(II) Acetylacetonate". Inorganic Syntheses. 6: 164–166. doi:10.1002/9780470132371.ch51. ISBN 978-0-470-13165-7.
  18. ^ Richert, S. A.; Tsang, P. K. S.; Sawyer, D. T. (1989). "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)]". Inorg. Chem. 28 (12): 2471–2475. doi:10.1021/ic00311a044.
  19. ^ a b Lennartson, Anders (2011). "Optical resolution and racemisation of [Fe(acac)3]". Inorg. Chim. Acta. 365: 451–453. doi:10.1016/j.ica.2010.07.066.
  20. ^ Bennett, M. A.; Heath, G. A.; Hockless, D. C. R.; Kovacik, I.; Willis, A. C. (1998). "Alkene Complexes of Divalent and Trivalent Ruthenium Stabilized by Chelation. Dependence of Coordinated Alkene Orientation on Metal Oxidation State". J. Am. Chem. Soc. 120 (5): 932–941. doi:10.1021/ja973282k.
  21. ^ Vreshch, V. D.; H. Zhang, J.-H. Yang; Filatov, A. S.; Dikarev, E. V. (2010). "Monomeric Square-Planar Cobalt(II) Acetylacetonate: Mystery or Mistake?". Inorg. Chem. 49 (18): 8430–8434. doi:10.1021/ic100963r. PMID 20795642.
  22. ^ Bennett, M. A.; Mitchell, T. R. B. (1976). "γ-Carbon-bonded 2,4-pentanedionato complexes of trivalent iridium". Inorg. Chem. 15 (11): 2936–8. doi:10.1021/ic50165a079.
  23. ^ Bhalla, G.; Oxgaard, J.; Goddard, W. A.; Periana, Roy A. (2005). "Hydrovinylation of Olefins Catalyzed by an Iridium Complex via CH Activation" (PDF). Organometallics. 24 (23): 5499–5502. doi:10.1021/om050614i.
  24. ^ Wong-Foy, A. G.; Bhalla, G.; Liu, X. Y.; Periana, R.A. (2003). "Alkane C–H Activation and Catalysis by an O-Donor Ligated Iridium Complex". J. Am. Chem. Soc. 125 (47): 14292–14293. doi:10.1021/ja037849a. PMID 14624574.
  25. ^ Tenn, William J.; Young, Kenneth J. H.; Bhalla, Gaurav; Oxgaard, Jonas; Goddard, William A.; Periana, Roy A. (2005). "CH Activation with an O-Donor Iridium-Methoxo Complex" (PDF). J. Am. Chem. Soc. 127 (41): 14172–14173. doi:10.1021/ja051497l. PMID 16218597.
  26. ^ Döhring, A.; Goddard, R.; Jolly, P. W.; Krüger, C.; Polyakov, V. R. (2007). "Monomer–Trimer Isomerism in 3-Substituted Pentane-2,4-dione Derivatives of Nickel(II)". Inorg. Chem. 36 (2): 177–183. doi:10.1021/ic960441c.
  27. ^ Williams, Paul; Jones, Anthony; Bickley, Jamie; Steiner, Alexander; Davies, Hywel; Leedham, Timothy; Impey, Susan; Garcia, Joanne; Allen, Stephen; Rougier, Aline; Blyr, Alexandra (2 August 2001). "Synthesis and crystal structures of dimethylaminoethanol adducts of Ni(ii) acetate and Ni(ii) acetylacetonate. Precursors for the sol–gel deposition of electrochromic nickel oxide thin films". Journal of Materials Chemistry. 11 (9). Royal Society of Chemistry: 2329–2334. doi:10.1039/B103288G. (subscription required)
  28. ^ Parish, E. J.; Li, S. (2004). "Copper(I) Acetylacetonate". In Paquette, L. (ed.). Encyclopedia of Reagents for Organic Synthesis. New York, NY: J. Wiley & Sons. doi:10.1002/047084289X.rc203. ISBN 0-471-93623-5.
  29. ^ Montgomery, H.; Lingafelter, E. C. (1963). "The crystal structure of monoaquobisacetylacetonatozinc". Acta Crystallographica. 16 (8): 748–752. doi:10.1107/S0365110X6300195X.
  30. ^ Barta, N. (2004). "Bis(acetylacetonato)zinc(II)". In Paquette, L. (ed.). Encyclopedia of Reagents for Organic Synthesis. New York, NY: J. Wiley & Sons. doi:10.1002/047084289X.rb097. ISBN 0-471-93623-5.
  31. ^ Rudolph, G.; Henry, M. C. (1967). "Bis(2,4-Pentanedionato)zinc (Zinc Acetylacetonate)". Inorg. Synth. 10: 74–77. doi:10.1002/9780470132418.ch14.
  32. ^ Koiwa, Tomohiro; Masuda, Yuki; Shono, Junpei; Kawamoto, Yuji; Hoshino, Yoshimasa; Hashimoto, Takeshi; Natarajan, Karuppannan; Shimizu, Kunio (2004). "Synthesis, Characterization, and Detailed Electrochemistry of Binuclear Ruthenium(III) Complexes Bridged by Bisacetylacetonate. Crystal and Molecular Structures of [{Ru(acac)2}2(tae)] (Acac = 2,4-Pentanedionate Ion, tae = 1,1,2,2-Tetraacetylethanate Dianion)". Inorganic Chemistry. 43 (20): 6215–6223. doi:10.1021/ic030216c. PMID 15446866.
  33. ^ Basato, Marino; Caneva, Elisabetta; Tubaro, Cristina; Veronese, Augusto Cesare (2009). "Coordinating Properties of the Anionic Ligand (MeCO)2C(−)C(X)Me (X=O or NH) Toward Transition Metal(II) Centers". Inorganica Chimica Acta. 362 (8): 2551–2555. doi:10.1016/j.ica.2008.11.017.
  34. ^ Murtha, D. P.; Lintvedt, Richard L. (1970). "Bis(1,3,5-triketonato)dicopper(II)chelates. Ferromagnetic and antiferromagnetic exchange between copper(II) ions". Inorganic Chemistry. 9 (6): 1532–1535. doi:10.1021/ic50088a046.