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Transition metal carbene complex

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A transition metal carbene complex is an organometallic compound featuring a divalent organic ligand. The divalent organic ligand coordinated to the metal center is called a carbene. Carbene complexes for almost all transition metals have been reported. Many methods for synthesizing them and reactions utilizing them have been reported. The term carbene ligand is a formalism since many are not derived from carbenes and almost none exhibit the reactivity characteristic of carbenes. Described often as M=CR2, they represent a class of organic ligands intermediate between alkyls (-CR3) and carbynes (≡CR). They feature in some catalytic reactions, especially alkene metathesis, and are of value in the preparation of some fine chemicals.

Classification of carbene complexes

Metal carbene complexes are often classified into two types. The Fischer carbenes named after Ernst Otto Fischer feature strong π-acceptors at the metal and being electrophilic at the carbene carbon atom. Schrock carbenes, named after Richard R. Schrock, are characterized by more nucleophilic carbene carbon centers, these species typically feature higher valent metals. N-heterocyclic carbenes (NHCs) were popularlized following Arduengo's isolation of a stable free carbene in 1991.[1] Reflecting the growth of the area, carbene complexes are now known with a broad range of different reactivities and diverse substituents. Often it is not possible to classify a carbene complex with regards to its electrophilicity or nucleophilicity.

Fischer carbenes

Fischer carbenes are found with:

The chemical bonding (Scheme 1) is based on σ-type electron donation of the filled lone pair orbital of the carbene atom to an empty metal d-orbital, and pi electron back bonding of a filled metal d-orbital to the empty p-orbital on carbon. An example is the complex (CO)5Cr=C(NR2)Ph.

Fischer carbenes can be likened to ketones, with the carbene carbon being electrophilic, much like the carbonyl carbon of a ketone. Like ketones, Fischer carbene species can undergo Aldol-like reactions. The hydrogen atoms attached to the carbon α to the carbene carbon are acidic, and can be deprotonated by a base such as n-butyllithium, to give a nucleophile which can undergo further reaction.[3]

This carbene is the starting material for other reactions such as the Wulff-Dötz reaction.

Schrock carbenes

Schrock carbenes do not have π-accepting ligands. These complexes are nucleophilic at the carbene carbon atom. Schrock carbenes are typically found with:

  • high oxidation state metal center
  • early transition metals Ti(IV), Ta(V)
  • pi-donor ligands
  • hydrogen and alkyl substituents on carbenoid carbon.

Bonding in such complexes can be viewed as the coupling of a triplet state metal and triplet carbene. These bonds are polarized towards carbon and therefore the carbene atom is a nucleophile. An example of a Schrock carbene is the compound Ta(=C(H)But)(CH2But)3, with a tantalum(V) center doubly bonded to a neopentylidene ligand as well as three neopentyl ligands. An example of interest in organic synthesis is Tebbe's reagent.

Scheme 1. Transition metal carbenes
Scheme 1. Transition metal carbenes

N-heterocyclic carbenes

IMes is a common NHC ligand.

N-heterocyclic carbenes (NHCs) are particularly common carbene ligands.[4] They are popular because they are more readily prepared than Schrock and Fischer carbenes. In fact many NHCs are isolated as the free ligand, since they are persistent carbenes. Being strongly stabilized by pi-donating substituents, NHCs are powerful σ-donors but π-bonding with the metal is weak.[5] For this reason, the bond between the carbon and the metal center is often represented by a single dative bond, whereas Fischer and Schrock carbenes are usually depicted with double bonds to metal. Continuing with this analogy, NHCs are often compared with trialkylphosphine ligands. Like phosphines, NHCs serve as spectator ligands that influence catalysis through a combination of electronic and steric effects, but they do not directly bind substrates.[6][7] Carbenes without a metal ligand have been produced in the lab.[8][9]

Applications of carbene complexes

The main applications of metal carbenes involves none of the above classes of compounds, but rather heterogeneous catalysts used for alkene metathesis in the Shell higher olefin process. A variety of related reactions are used to interconvert light alkenes, e.g. butenes, propylene, and ethylene. Carbene-complexes are invoked as intermediates in the Fischer-Tropsch route to hydrocarbons. A variety of soluble carbene reagents, especially the Grubbs' and molybdenum-imido catalysts have been applied to laboratory-scale synthesis of natural products and materials science. In the nucleophilic abstraction reaction, a methyl group can be abstracted from a Fischer carbene for further reaction.

History

The characterization of (CO)5W(COCH3(Ph)) in the 1960s is often cited as the starting point of the area,[10] although carbenoid ligands had been previously implicated. E. O. Fischer, for this and other achievements in organometalic chemistry, was awarded the Nobel prize.[10]

The first metal carbene complex, Chugaev's red salt, was not recognized as such until decades after its preparation.[4]

See also

References

  1. ^ A. J. Arduengo, R. L. Harlow and M. Kline (1991). "A stable crystalline carbene". J. Am. Chem. Soc. 113 (1): 361–363. doi:10.1021/ja00001a054.
  2. ^ Lous S. Hegedus, Michael A. Mcguire, And Lisa M. Schultze "1,3-Dimethyl-3-methoxy-4-phenylazetidinone" Org. Synth. 1987, volume 65, 140 doi:10.15227/orgsyn.065.0140
  3. ^ Robert H. Crabtree (2005). The Organometallic Chemistry of the Transition Metals (4th ed.). New Jersey: Wiley-Interscience. ISBN 0-471-66256-9.
  4. ^ a b F. Ekkehardt Hahn, Mareike C. Jahnke Dr. "Heterocyclic Carbenes: Synthesis and Coordination Chemistry"Angewandte Chemie International Edition 2008, Volume 47, pp. 3122–3172. doi:10.1002/anie.200703883
  5. ^ Fillman, Kathlyn L.; Przyojski, Jacob A.; Al-Afyouni, Malik H.; Tonzetich, Zachary J.; Neidig, Michael L. "A combined magnetic circular dichroism and density functional theory approach for the elucidation of electronic structure and bonding in three- and four-coordinate iron( ii )–N-heterocyclic carbene complexes". Chem. Sci. 6 (2): 1178–1188. doi:10.1039/c4sc02791d. PMC 4302958. PMID 25621143.
  6. ^ Przyojski, Jacob A.; Veggeberg, Kevin P.; Arman, Hadi D.; Tonzetich, Zachary J. (2015-09-08). "Mechanistic Studies of Catalytic Carbon–Carbon Cross-Coupling by Well-Defined Iron NHC Complexes". ACS Catalysis. 5 (10): 5938–5946. doi:10.1021/acscatal.5b01445.
  7. ^ Przyojski, Jacob A.; Arman, Hadi D.; Tonzetich, Zachary J. (2012-12-18). "NHC Complexes of Cobalt(II) Relevant to Catalytic C–C Coupling Reactions". Organometallics. 32 (3): 723–732. doi:10.1021/om3010756.
  8. ^ Aldeco-Perez, E.; Rosenthal, A. J.; Donnadieu, B.; Parameswaran, P.; Frenking, G.; Bertrand, G. (October 2009). "Isolation of a C5-Deprotonated Imidazolium, a Crystalline "Abnormal" N-Heterocyclic Carbene". Science. 326 (5952): 556–559. Bibcode:2009Sci...326..556A. doi:10.1126/science.1178206. PMC 2871154. PMID 19900893.
  9. ^ Arduengo, Anthony J.; Goerlich, Jens R.; Marshall, William J. (2002-05-01). "A stable diaminocarbene". Journal of the American Chemical Society. 117 (44): 11027–11028. doi:10.1021/ja00149a034.
  10. ^ a b E. O. Fischer, A. Maasböl (1964). "On the Existence of a Tungsten Carbonyl Carbene Complex". Angewandte Chemie International Edition in English. 3 (8): 580–581. doi:10.1002/anie.196405801.