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Hiyama coupling

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Hiyama coupling
Named after Tamejiro Hiyama
Reaction type Coupling reaction
Identifiers
Organic Chemistry Portal hiyama-coupling
RSC ontology ID RXNO:0000193

The Hiyama coupling is a palladium-catalyzed cross-coupling reaction of organosilanes with organic halides used in organic chemistry to form carbon–carbon bonds (C-C bonds). This reaction was discovered in 1988 by Tamejiro Hiyama and Yasuo Hatanaka as a method to form carbon-carbon bonds synthetically with chemo- and regioselectivity.[1] The Hiyama coupling has been applied to the synthesis of various natural products.[2]

  • : aryl, alkenyl or alkynyl
  • : aryl, alkenyl, alkynyl or alkyl
  • : Cl, F or alkyl
  • : Cl, Br, I or OTf

Reaction history

The Hiyama coupling was developed to combat the issues associated with other organometallic reagents. The initial reactivity of organosilicon was not actually first reported by Hiyama, as Kumada reported a coupling reaction using organofluorosilicates[3] shown below. Organosilanes were then discovered, by Hiyama, to have reactivity when activated by a fluoride source.[4][5] This reactivity, when combined with a palladium salt, creates a carbon-carbon bond with an electrophillic carbon, like an organic halide. Compared to the inherent issues of well-used organometalics reagents, such as organomagnesium (Grignard Reagents) and organocopper reagents, which are very reactive and are known to have low chemoselectivity, enough to destroy functional groups on both coupling partners, organosilicon compounds are inactive. Other organometallic reagents using metals such as zinc, tin, and boron, reduce the reactivity issue, but have other problems associated with each reagent. Organozinc reagents are moisture sensitive, organotin compounds are toxic, and organoboron reagents are not readily available, are expensive, and aren't often stable. Organosilanes are readily available compounds that, upon activation (much like organotin or organoboron compounds) from fluoride or a base, can react with organohalides to form C-C bonds in a chemo- and regioselective manner. The reaction first reported was used to couple easily made (and activated) organosilicon nucleophiles and organohalides (electrophiles) in the presence of a palladium catalyst.[1] Since this discovery, work has been done by various groups to expand the scope of this reaction and to "fix" the issues with this first coupling, such as the need for fluoride activation of the organosilane.

Silicate coupling precedent for development of the Hiyama coupling[3]

Mechanism

The organosilane is activated with fluoride (as some sort of salt such as TBAF or TASF) or a base to form a pentavalent silicon center which is labile enough to allow for the breaking of a C-Si bond during the transmetalation step.[6] The general scheme to form this key intermediate is shown below. This step occurs in-situ or at the same time as the catalytic cycle in the reaction.

The mechanism for the Hiyama coupling follows a catalytic cycle, including an A) oxidative addition step, in which the organichalide adds to the palladium oxidizing the metal from palladium(0) to palladium(II); a B) transmetalation step, in which the C-Si bond is broken and the second carbon fragment is bound to the palladium center; and finally C) a reductive elimination step, in which the C-C bond is formed and the palladium returns to its zero-valent state to start the cycle over again.[7] The catalytic cycle is shown below.

The Catalytic Cycle of the Hiyama coupling
The Catalytic Cycle of the Hiyama coupling

Scope and limitations

Scope

The Hiyama coupling can be applied to the formation of Csp2-Csp2 (e.g. aryl–aryl) bonds as well as Csp2-Csp3 (e.g. aryl–alkyl) bonds. Good synthetic yields are obtained with couplings of aryl halides, vinyl halides, and allylic halides and organo iodides afford the best yields. The scope of this reaction was expanded to include closure of medium-sized rings by Scott E. Denmark.[8]

Hiyama coupling as a ring-closing reaction. Note, that there will be an 8 Carbonatom ring instead the shown 10-Carbon ring. (See the Paper)
Hiyama coupling as a ring-closing reaction[8]

The coupling of alkyl halides with organo-halo-silanes as alternative organosilanes has also been performed. Organochlorosilanes allow couplings with aryl chlorides, which are abundant and generally more economical than aryl iodides.[9] A nickel catalyst allows for access to new reactivity of organotrifluorosilanes as reported by GC Fu et al.[10] Secondary alkyl halides are coupled with aryl silanes[11] with good yields using this reaction.

The Nickel-catalyzed Hiyama coupling as discovered by GC Fu et al.
The Nickel-catalyzed Hiyama coupling as discovered by GC Fu et al.

Limitations

The Hiyama coupling is limited by the need for fluoride in order to activate the organosilicon reagent. Addition of fluoride cleaves any silicon protecting groups (e.g. silyl ethers[12]), which are frequently employed in organic synthesis. The fluoride ion is also basic, so base sensitive protecting groups, acidic protons, and functional groups may be affected by the addition of this activator. Most of the active research concerning this reaction involves circumventing this problem. To overcome this issue, many groups have looked to the use of other basic additives for activation, or use of a different organosilane reagent all together, leading to the multiple variations of the original Hiyama coupling.

Variations

One modification of the Hiyama coupling utilizes a silacyclobutane ring and a fluoride source that is hydrated as shown below.[13] This mimics the use of an alkoxysilane/organosilanol rather than the use of alkylsilane. The mechanism of this reaction, using a fluoride source, allowed for the design of future reactions that can avoid the use of the fluoride source.

Proposed transition state of Denmark's Hiyama coupling of silacyclobutanes[13]

Fluoride-free Hiyama couplings

Many modifications to the Hiyama coupling have been developed that avoid the use of a fluoride activator/base. Using organochlorosilanes, Hiyama found a coupling scheme utilizing NaOH as the basic activator.[14] Modifications using alkoxysilanes have been reported with the use of milder bases like NaOH [15] and even water.[16] Study of these mechanisms have led to the development of the Hiyama–Denmark coupling which utilize organosilanols as coupling partners.

NaOH-promoted Hiyama coupling[14]


Another class of fluoride-free Hiyama couplings include the use of a Lewis acid additive, which allows for bases such as K3PO4[17] to be utilized, or for the reaction to proceed without a basic additive.[18][19] The addition of a copper co-catalyst has also been reported to allow for the use of a milder activating agent[17] and has even been shown to get turnover in which both the palladium(II) and copper(I) turnover in the catalytic cycle rather than addition of stoichiometric Lewis acid (e.g. silver(I),[18] copper(I)[19]).

Hiyama coupling with a copper co-catalyst[17]

Hiyama–Denmark coupling

Hiyama–Denmark coupling
Named after Tamejiro Hiyama
Scott E. Denmark
Reaction type Coupling reaction
Identifiers
Organic Chemistry Portal hiyama-denamrk-coupling

The Hiyama–Denmark coupling is the modification of the Hiyama coupling that does not require a fluoride additive to utilize organosilanols and organic halides as coupling partners. The general reaction scheme is shown below, showcasing the utilization of a Brønsted base as the activating agent as opposed to fluoride, phosphine ligands are also used on the metal center.[2]

General scheme of the Hiyama–Denmark coupling
General scheme of the Hiyama–Denmark coupling

A specific example of this reaction is shown with reagents. If fluoride had been used, as in the original Hiyama protocol, the tert-butyldimethylsilyl (TBS) ether would have likely been destroyed.[20]

Example of silanol coupling without fluoride additives[20]

Hiyama–Denmark coupling mechanism

Examination of this reaction's mechanism suggests that the formation of the silonate is all that is needed to activate addition of the organosilane to the palladium center. The presence of a pentavalent silicon is not needed and kinetic analysis has shown that this reaction has first order dependence on silonate concentration.[2] This is due to the key bond being formed, the Pd-O bond during the transmetalation step, that then allows for transfer of the carbon fragment onto the palladium center. Based on this observation, it seems that the rate limiting step in this catalytic cycle is the Pd-O bond formation, in which increased silonate concentrations increase the rate of this reaction (indicative of faster reactions).

Catalytic cycle of the Hiyama–Denmark coupling
Catalytic cycle of the Hiyama–Denmark coupling

See also

References

  1. ^ a b Hatanaka, Y.; Hiyama, T. (1988). "Cross-coupling of organosilanes with organic halides mediated by a palladium catalyst and tris(diethylamino)sulfonium difluorotrimethylsilicate". Journal of Organic Chemistry. 53 (4): 918–920. doi:10.1021/jo00239a056.
  2. ^ a b c Denmark, S. E.; Regens, C. S. (2008). "Palladium-Catalyzed Cross-Coupling Reactions of Organosilanols and Their Salts: Practical Alternatives to Boron- and Tin-Based Methods". Accounts of Chemical Research. 41 (11): 1486–1499. doi:10.1021/ar800037p. PMC 2648401.
  3. ^ a b Yoshida, J.; Tamao, K.; Yamamoto, H.; Kakui, T.; Uchida, T.; Kumada, M. (1982), "Organofluorosilicates in organic synthesis. 14. Carbon-carbon bond formation promoted by palladium salts", Organometallics, 1: 542, doi:10.1021/om00063a025
  4. ^ Hiyama, T.; Obayashi, M.; Mori, I.; Nozaki, H. (1983), "Generation of metal-free silyl anions from disilanes and fluoride catalyst. Synthetic reactions with aldehydes and 1,3-dienes", The Journal of Organic Chemistry, 48: 912, doi:10.1021/jo00154a043
  5. ^ Fujita, M.; Hiyama, T. (1988), "Erythro-directive reduction of .alpha.-substituted alkanones by means of hydrosilanes in acidic media", The Journal of Organic Chemistry, 53: 5415, doi:10.1021/jo00258a004
  6. ^ Hiyama, T. (2002), "How I came across the silicon-based cross-coupling reaction", Journal of Organometallic Chemistry, 653: 58, doi:10.1016/s0022-328x(02)01157-9
  7. ^ Miyaura, N.; Suzuki, A. (1995), "Palladium-Catalyzed Cross-Coupling Reactions of Organoboron Compounds", Chemical Reviews, 95: 2457, doi:10.1021/cr00039a007
  8. ^ a b Denmark, S. E.; Yang, S.-M. (2002), "Intramolecular Silicon-Assisted Cross-Coupling Reactions:  General Synthesis of Medium-Sized Rings Containing a 1,3-cis-cis Diene Unit", Journal of the American Chemical Society, 124: 2102, doi:10.1021/ja0178158
  9. ^ Gouda, K.-i.; Hagiwara, E.; Hatanaka, Y.; Hiyama, T. (1996), "Cross-Coupling Reactions of Aryl Chlorides with Organochlorosilanes:  Highly Effective Methods for Arylation or Alkenylation of Aryl Chlorides", The Journal of Organic Chemistry, 61: 7232, doi:10.1021/jo9611172
  10. ^ Powell, D. A.; Fu, G. C. (2004), "Nickel-Catalyzed Cross-Couplings of Organosilicon Reagents with Unactivated Secondary Alkyl Bromides", Journal of the American Chemical Society, 126: 7788, doi:10.1021/ja047433c
  11. ^ Strotman, N. A.; Sommer, S.; Fu, G. C. (2007), "Hiyama Reactions of Activated and Unactivated Secondary Alkyl Halides Catalyzed by a Nickel/Norephedrine Complex", Angewandte Chemie International Edition, 46: 3556, doi:10.1002/anie.200700440
  12. ^ Greene, T. W.; Wuts, P. G. M. Protective Groups In Organic Synthesis, 3rd ed.; John Wiley & Sons: New York, 1991. ISBN 0471160199
  13. ^ a b Denmark, S. E.; Wehrli, D.; Choi, J. Y. (2000), "Convergence of Mechanistic Pathways in the Palladium(0)-Catalyzed Cross-Coupling of Alkenylsilacyclobutanes and Alkenylsilanols", Organic Letters, 2: 2491, doi:10.1021/ol006170y
  14. ^ a b Hagiwara, E.; Gouda, K.-i.; Hatanaka, Y.; Hiyama, T. (1997), "NaOH-Promoted cross-coupling reactions of organosilicon compounds with organic halides: Practical routes to biaryls, alkenylarenes and conjugated dienes", Tetrahedron Letters, 38: 439, doi:10.1016/s0040-4039(96)02320-9
  15. ^ Shi, S.; Zhang, Y. (2007), "Pd(OAc)2-Catalyzed Fluoride-Free Cross-Coupling Reactions of Arylsiloxanes with Aryl Bromides in Aqueous Medium", The Journal of Organic Chemistry, 72: 5927, doi:10.1021/jo070855v
  16. ^ Wolf, C.; Lerebours, R. (2004), "Palladium−Phosphinous Acid-Catalyzed NaOH-Promoted Cross-Coupling Reactions of Arylsiloxanes with Aryl Chlorides and Bromides in Water", Organic Letters, 6: 1147, doi:10.1021/ol049851s
  17. ^ a b c Nakao, Y.; Takeda, M.; Matsumoto, T.; Hiyama, T. (2010), "Cross-Coupling Reactions through the Intramolecular Activation of Alkyl(triorgano)silanes", Angewandte Chemie, 122: 4549, doi:10.1002/ange.201000816
  18. ^ a b Hirabayashi, K.; Mori, A.; Kawashima, J.; Suguro, M.; Nishihara, Y.; Hiyama, T. (2000), "Palladium-Catalyzed Cross-Coupling of Silanols, Silanediols, and Silanetriols Promoted by Silver(I) Oxide", The Journal of Organic Chemistry, 65: 5342, doi:10.1021/jo000679p
  19. ^ a b Nishihara, Y.; Ikegashira, K.; Hirabayashi, K.; Ando, J.-i.; Mori, A.; Hiyama, T. (2000), "Coupling Reactions of Alkynylsilanes Mediated by a Cu(I) Salt:  Novel Syntheses of Conjugate Diynes and Disubstituted Ethynes", The Journal of Organic Chemistry, 65: 1780, doi:10.1021/jo991686k
  20. ^ a b Denmark, S. E.; Smith, R. C.; Chang, W.-T. T.; Muhuhi, J. M. (2009), "Cross-Coupling Reactions of Aromatic and Heteroaromatic Silanolates with Aromatic and Heteroaromatic Halides", Journal of the American Chemical Society, 131: 3104, doi:10.1021/ja8091449, PMC 2765516