Blanc chloromethylation

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Blanc chloromethylation
Named afterGustave Louis Blanc
Reaction type Substitution reaction
Identifiers
Organic Chemistry Portal blanc-reaction

The Blanc chloromethylation (also called the Blanc reaction) is the chemical reaction of aromatic rings with formaldehyde and hydrogen chloride to form chloromethyl arenes. The reaction is catalyzed by Lewis acids such as zinc chloride. [1] The reaction was discovered by Gustave Louis Blanc (1872-1927) in 1923 [2] [3]

Contents

Blanc chloromethylation Blanc Chloromethylation Reaction Scheme.png
Blanc chloromethylation

Mechanism and scope

The reaction is carried out under acidic conditions and with a ZnCl2 catalyst. These conditions protonate the formaldehyde carbonyl making the carbon much more electrophilic. The aldehyde is then attacked by the aromatic pi-electrons, followed by rearomatization of the aromatic ring. The benzyl alcohol thus formed is quickly converted to the chloride under the reaction conditions.

Mechanism of Blanc chloromethylation ChloromethylationMechanism.png
Mechanism of Blanc chloromethylation

Other possibilities for the electrophile include (chloromethyl)oxonium cation (ClH2C–OH2+) or chlorocarbenium cation (ClCH2+), which may be formed in the presence of zinc chloride. [4] These species may account for the fact that moderately and strongly deactivated substrates that are inert to Friedel-Crafts reactions like acetophenone, nitrobenzene and p-chloronitrobenzene [5] do show marginal reactivity of limited synthetic utility under chloromethylation conditions. [6] Deactivated substrates give better results under modified chloromethylation conditions using chloromethyl methyl ether (MOMCl) in the presence of 60% H2SO4. [4]

Highly activated arenes like phenols and anilines are not suitable substrates, since they undergo further electrophilic attack by Friedel-Crafts alkylation with the formed benzylic alcohol/chloride in an uncontrolled manner. In general, the formation of diarylmethane side product is a common outcome. [6]

Although the reaction is an efficient means of introducing a chloromethyl group, the production of small amounts of highly carcinogenic bis(chloromethyl) ether is a disadvantage for industrial applications.

The corresponding fluoromethylation, bromomethylation and iodomethylation reactions can also be achieved, using the appropriate hydrohalic acid. [7]

Chloromethylation of thiols can be effected with concentrated HCl and formaldehyde: [8]

ArSH + CH2O + HCl → ArSCH2Cl + H2O

Chloromethylation can also be effected using chloromethyl methyl ether:

ArH + CH3OCH2Cl → ArCH2Cl + CH3OH

This reaction is employed in the chloromethylation of styrene in the production of ion-exchange resins and Merrifield resins. [9]

Additional reading

Safety

The reaction is performed with care as, like most chloromethylation reactions, it produces highly carcinogenic bis(chloromethyl) ether as a by-product.

See also

Related Research Articles

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References

  1. Belen'kii, Leonid I; Vol'kenshtein, Yu B; Karmanova, I B (30 September 1977). "New Data on the Chloromethylation of Aromatic and Heteroaromatic Compounds". Russian Chemical Reviews . 46 (9): 891–903. Bibcode:1977RuCRv..46..891B. doi:10.1070/RC1977v046n09ABEH002180. S2CID   250898192.
  2. Blanc, Gustave Louis (1923). "Sur la préparation de dérivés chlorométhyléniques aromatiques". Bulletin de la Société Chimique de France . Série 4. 33: 313–319.
  3. Grassi, G.; Maselli, C. (1898). "Su alcuni derivati clorurati de trossimetilene" [On some chlorinated derivatives of 1,3,5-trioxane]. Gazzetta Chimica Italiana . 28 (pt 2): 477–500 [495].
  4. 1 2 Laali, Kenneth K. (2001). "Formaldehyde–Hydrogen Chloride". Encyclopedia of Reagents for Organic Synthesis . American Cancer Society. doi:10.1002/047084289x.rf022. ISBN   978-0-470-84289-8.
  5. 研藏, 白川; 泰三, 松川 (1950-01-25). "Chloromethylation of Benzene Nucleus II". Yakugaku Zasshi (in Japanese). 70 (1): 25–28. doi: 10.1248/yakushi1947.70.1_25 . ISSN   0031-6903.
  6. 1 2 McKeever, C. H.; Fuson, Reynold C. (2011-03-15). "Chloromethylation of Aromatic Compounds". Organic Reactions. American Cancer Society. pp. 63–90. doi:10.1002/0471264180.or001.03. ISBN   978-0-471-26418-7.
  7. C., Norman, Richard O. (2017). Principles of Organic Synthesis. Coxon, James M. (3rd ed.). Boca Raton: Routledge. ISBN   978-1-351-42173-7. OCLC   1042320639.
  8. D. Enders; S. Von Berg; B. Jandeleit (2002). "Diethyl [(Phenylsulfonyl)methyl]phosphonate". Organic Syntheses . 78: 169. doi:10.15227/orgsyn.078.0169.
  9. Dardel, François; Arden, Thomas V. (2008). "Ion Exchangers". Ullmann's Encyclopedia of Industrial Chemistry . Weinheim: Wiley-VCH. doi:10.1002/14356007.a14_393.pub2.
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