Chemistry:Carbon-carbon bond activation

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Short description: Process of breaking bonds between carbon atoms

Carbon-carbon bond activation refers to the breaking of carbon-carbon bonds in organic molecules. This process is an important tool in organic synthesis, as it allows for the formation of new carbon-carbon bonds and the construction of complex organic molecules.[1] However, C–C bond activation is challenging mainly for the following reasons: (1) C-H bond activation is a competitive process of C-C activation, which is both energetically and kinetically more favorable; (2) the accessibility of the transition metal center to C–C bonds is generally difficult due to its 'hidden' nature; (3) relatively high stability of the C–C bond (90 kcal/mol−1). As a result, in the early stage, most examples of C-C activation are of stringed ring systems,[2][3] which makes C-C activation more favorable by increasing the energy of the starting material. However, C-C activation of unstrained C-C bonds has remained challenging until the recent two decades.

Examples of C-C bond activation

Due to the difficulty of C-C activation, a driving force is required to facilitate the reaction. One common strategy is to form stable metal complexes. One example is reported by Milstein and coworkers, in which the C(sp2)–C(sp3) bond of bisphosphine ligands was selectively cleaved by a number of metals to afford stable pincer complexes under mild conditions.[4][5][6]

C-C bond activation driven by the formation of stable metal complexes

Aromatization is another driving force that is utilized for C–C bond activation. For example, Chaudret group reported that the C–C bond of steroid compounds can be cleaved through the Ru-promoted aromatization of the B ring.[7] At the same time, a methane molecule is released, which is possibly another driving force for this reaction.

C-C activation driven by aromatization

In addition, the metalloradical has also been proven to have the ability to cleave the C–C single bond. Chan group reported the C–C bond scission of cyclooctane via 1,2-addition with Rh(III) porphyrin hydride, which involved [RhII(ttp)]· radical as the key intermediate.[8]

C-C bond activation catalyzed by transition metal radicals

Mechanism of C-C bond activation

Generally speaking, there are two distinct mechanistic pathways that lead to C-C bond activation: (a) the β-carbon elimination of metal complexes. In this mechanism, a M–C intermediate and a double bond are formed at the same time; and (b) the direct oxidative addition of C–C bonds into low-valent metal adducts to form a bis(organyl)metal complex.

Two distinct pathways for C-C activation

β-carbon elimination

In 1997, Tamaru group reported the first metal-catalyzed β-carbon elimination of an unstrained compound.[9] Their work revealed a novel Pd(0)-catalyzed ring opening of 4-vinyl cyclic carbonates. They proposed that the reaction is initiated by the elimination of carbon dioxide to form π-allylpalladium intermediate, which is followed by β-decarbopalladation to form dienals and dienones. Since then, this field has bloomed, and a lot of similar reactions were developed and showed their great potential in organic synthesis. The early stage of research in this field has focused on the reaction of M–O–C–C species and β-carbon elimination of the M–N–C–C intermediate was not discovered until the recent ten years. In 2010, Nakamura reported a Cu-catalyzed substitution reaction of propargylic amines with alkynes or other amines as the first example of the transition-metal-catalyzed β-carbon elimination of amines.[10]

First example of metal-catalyzed β-carbon elimination of unstrained compounds

Oxidative addition

Compared with β-carbon elimination, oxidative addition of C-C bond is a more direct way of C-C bond activation. However, it is more challenging to do for the following reasons: 1) It forms two weak M-C bonds at the expense of breaking a stable C-C bond, so it is energetically unfavorable; 2) the C-C bond is usually hindered, which makes the metal center hard to approach. As a result, the cleavage of unstrained compounds that have been achieved is mainly focused on ketone substrates. This is because the C–C bond adjacent to the carbonyl of ketones is weaker and can be much more easily cleaved. It also benefits from the less steric hindrance from the planar structure of the carbonyl motif. Suggs and Jun are pioneers in this field. They found that an Rh(I) complex, [RhCl(C2H4)2]2, can be oxidatively inserted into the C–C bond of 8-acylquinolines at the 8-position to form relatively stable 5-membered rhodacycles. Subsequently, 8-acylquinoline can be coupled with ethylene to afford 8-quinolinyl ethylketone, which represented the first transition-metal-catalyzed scission of C–C bonds via oxidative addition.[11]

First example of transition-metal-catalyzed scission of C–C via oxidative addition

Applications of C-C bond activation

Carbon-carbon bond activation reactions have numerous applications in organic synthesis, materials science, and pharmaceuticals. In organic synthesis, these reactions are used to construct complex molecules in a highly efficient and selective manner. For example, in 2021 Dong Group described the first enantioselective total synthesis of the natural product penicibilaenes using a late-stage carbon-carbon bond activation strategy.[12] There are also a lot of other examples highlighting the potential of carbon-carbon bond activation strategies in the total synthesis of complex natural products with high stereocontrol.

References

  1. Song, Feijie; Gou, Ting; Wang, Bi-Qin; Shi, Zhang-Jie (2018-09-17). "Catalytic activations of unstrained C–C bond involving organometallic intermediates". Chemical Society Reviews 47 (18): 7078–7115. doi:10.1039/C8CS00253C. ISSN 1460-4744. PMID 30112546. https://pubs.rsc.org/en/content/articlelanding/2018/cs/c8cs00253c. 
  2. Crabtree, Robert H. (1985-08-01). "The organometallic chemistry of alkanes". Chemical Reviews 85 (4): 245–269. doi:10.1021/cr00068a002. ISSN 0009-2665. https://pubs.acs.org/doi/abs/10.1021/cr00068a002. 
  3. Periana, Roy A.; Bergman, Robert G. (November 1986). "Carbon-carbon activation of organic small ring compounds by arrangement of cycloalkylhydridorhodium complexes to rhodacycloalkanes. Synthesis of metallacyclobutanes, including one with a tertiary metal-carbon bond, by nucleophilic addition to .pi.-allyl complexes". Journal of the American Chemical Society 108 (23): 7346–7355. doi:10.1021/ja00283a033. ISSN 0002-7863. https://pubs.acs.org/doi/abs/10.1021/ja00283a033. 
  4. Gozin, Michael; Weisman, Alexander; Ben-David, Yehoshua; Milstein, David (August 1993). "Activation of a carbon–carbon bond in solution by transition-metal insertion". Nature 364 (6439): 699–701. doi:10.1038/364699a0. ISSN 1476-4687. Bibcode1993Natur.364..699G. https://www.nature.com/articles/364699a0. 
  5. Murakami, Masahiro; Amii, Hideki; Ito, Yoshihiko (August 1994). "Selective activation of carbon–carbon bonds next to a carbonyl group". Nature 370 (6490): 540–541. doi:10.1038/370540a0. ISSN 1476-4687. Bibcode1994Natur.370..540M. https://www.nature.com/articles/370540a0. 
  6. Albrecht, Martin; Lindner, Monika M. (2011-08-23). "Cleavage of unreactive bonds with pincer metal complexes". Dalton Transactions 40 (35): 8733–8744. doi:10.1039/C1DT10339C. ISSN 1477-9234. https://pubs.rsc.org/en/content/articlelanding/2011/dt/c1dt10339c. 
  7. Halcrow, Malcolm A.; Urbanos, Francisco; Chaudret, Bruno (March 1993). "Aromatization of the B-ring of 5,7-dienyl steroids by the electrophilic ruthenium fragment "[Cp*Ru+""]. Organometallics 12 (3): 955–957. doi:10.1021/om00027a054. ISSN 0276-7333. https://pubs.acs.org/doi/abs/10.1021/om00027a054. 
  8. Chan, Yun Wai; Chan, Kin Shing (2010-05-26). "Metalloradical-Catalyzed Aliphatic Carbon−Carbon Activation of Cyclooctane". Journal of the American Chemical Society 132 (20): 6920–6922. doi:10.1021/ja101586w. ISSN 0002-7863. PMID 20441175. https://pubs.acs.org/doi/10.1021/ja101586w. 
  9. Harayama, Hiroto; Kuroki, Toshitsugu; Kimura, Masanari; Tanaka, Shuji; Tamaru, Yoshinao (1997-11-14). "Synthesis of Doubly Unsaturated Aldehydes and Ketones by a Novelβ-Decarbopalladation". Angewandte Chemie International Edition in English 36 (21): 2352–2354. doi:10.1002/anie.199723521. ISSN 0570-0833. https://onlinelibrary.wiley.com/doi/10.1002/anie.199723521. 
  10. Sugiishi, Tsuyuka; Kimura, Akifumi; Nakamura, Hiroyuki (2010-04-21). "Copper(I)-Catalyzed Substitution Reactions of Propargylic Amines: Importance of C(sp)−C(sp 3 ) Bond Cleavage in Generation of Iminium Intermediates". Journal of the American Chemical Society 132 (15): 5332–5333. doi:10.1021/ja9109055. ISSN 0002-7863. PMID 20353176. https://pubs.acs.org/doi/10.1021/ja9109055. 
  11. Suggs, J. William; Jun, Chul-Ho (1985-01-01). "Metal-catalysed alkyl ketone to ethyl ketone conversions in chelating ketones via carbon–carbon bond cleavage". Journal of the Chemical Society, Chemical Communications (2): 92–93. doi:10.1039/C39850000092. ISSN 0022-4936. https://pubs.rsc.org/en/content/articlelanding/1985/c3/c39850000092. 
  12. Xue, Yibin; Dong, Guangbin (2021-06-09). "Total Synthesis of Penicibilaenes via C–C Activation-Enabled Skeleton Deconstruction and Desaturation Relay-Mediated C–H Functionalization". Journal of the American Chemical Society 143 (22): 8272–8277. doi:10.1021/jacs.1c04335. ISSN 0002-7863. PMID 34038107.