The Dakin oxidation is an organic redox reaction in which an ortho- or para-hydroxylated phenyl aldehyde (2-hydroxybenzaldehyde or 4-hydroxybenzaldehyde) or ketone reacts with hydrogen peroxide in base to form a benzenediol and a carboxylate. Overall, the carbonyl group is oxidized, and the hydrogen peroxide is reduced.
- 1 Reaction mechanism
- 2 Factors affecting reaction kinetics
- 3 Variants
- 4 Synthetic applications
- 5 See also
- 6 References
The Dakin oxidation starts with nucleophilic addition of a hydroperoxide anion to the carbonyl carbon, forming a tetrahedral intermediate (2). The intermediate collapses, causing [1,2]-aryl migration, hydroxide elimination, and formation of a phenyl ester (3). The phenyl ester is subsequently hydrolyzed: nucleophilic addition of hydroxide from solution to the ester carbonyl carbon forms a second tetrahedral intermediate (4), which collapses, eliminating a phenoxide and forming a carboxylic acid (5). Finally, the phenoxide extracts the acidic hydrogen from the carboxylic acid, yielding the collected products (6).
Factors affecting reaction kinetics
The Dakin oxidation has two rate-limiting steps: nucleophilic addition of hydroperoxide to the carbonyl carbon and [1,2]-aryl migration. Therefore, the overall rate of oxidation is dependent on the nucleophilicity of hydroperoxide, the electrophilicity of the carbonyl carbon, and the speed of [1,2]-aryl migration. The alkyl substituents on the carbonyl carbon, the relative positions of the hydroxyl and carbonyl groups on the aryl ring, the presence of other functional groups on the ring, and the reaction mixture pH are four factors that affect these rate-limiting steps.
In general, phenyl aldehydes are more reactive than phenyl ketones because the ketone carbonyl carbon is less electrophilic than the aldehyde carbonyl carbon. The difference can be mitigated by increasing the temperature of the reaction mixture.
Relative positions of hydroxyl and carbonyl groups
O-hydroxy phenyl aldehydes and ketones oxidize faster than p-hydroxy phenyl aldehydes and ketones in weakly basic conditions. In o-hydroxy compounds, when the hydroxyl group is protonated, an intramolecular hydrogen bond can form between the hydroxyl hydrogen and the carbonyl oxygen, stabilizing a resonance structure with positive charge on the carbonyl carbon, thus increasing the carbonyl carbon’s electrophilicity (7). Lacking this stabilization, the carbonyl carbon of p-hydroxy compounds is less electrophilic. Therefore, o-hydroxy compounds are oxidized faster than p-hydroxy compounds when the hydroxyl group is protonated.
M-hydroxy compounds do not oxidize to m-benzenediols and carboxylates. Rather, they form phenyl carboxylic acids. Variations in the aryl rings' migratory aptitudes can explain this. Hydroxyl groups ortho or para to the carbonyl group concentrate electron density at the aryl carbon bonded to the carbonyl carbon (10c, 11d). Phenyl groups have low migratory aptitude, but higher electron density at the migrating carbon increases migratory aptitude, facilitating [1,2]-aryl migration and allowing the reaction to continue. M-hydroxy compounds do not concentrate electron density at the migrating carbon (12a, 12b, 12c, 12d); their aryl groups' migratory aptitude remains low. The benzylic hydrogen, which has the highest migratory aptitude, migrates instead (8), forming a phenyl carboxylic acid (9).
Other functional groups on the aryl ring
Substitution of phenyl hydrogens with electron-donating groups ortho or para to the carbonyl group increases electron density at the migrating carbon, promotes [1,2]-aryl migration, and accelerates oxidation. Substitution with electron-donating groups meta to the carbonyl group does not change electron density at the migrating carbon; because unsubstituted phenyl group migratory aptitude is low, hydrogen migration dominates. Substitution with electron-withdrawing groups ortho or para to the carbonyl decreases electron density at the migrating carbon (13c), inhibits [1,2]-aryl migration, and favors hydrogen migration.
The hydroperoxide anion is a more reactive nucleophile than neutral hydrogen peroxide. Consequently, oxidation accelerates as pH increases toward the pKa of hydrogen peroxide and hydroperoxide concentration climbs. At pH higher than 13.5, however, oxidation does not occur, possibly due to deprotonation of the second peroxidic oxygen. Deprotonation of the second peroxidic oxygen would prevent [1,2]-aryl migration because the lone oxide anion is too basic to be eliminated (2).
Deprotonation of the hydroxyl group increases electron donation from the hydroxyl oxygen. When the hydroxyl group is ortho or para to the carbonyl group, deprotonation increases the electron density at the migrating carbon, promoting faster [1,2]-aryl migration. Therefore, [1,2]-aryl migration is facilitated by the pH range that favors deprotonated over protonated hydroxyl group.
Acid-catalyzed Dakin oxidation
The Dakin oxidation can occur in mild acidic conditions as well, with a mechanism analogous to the base-catalyzed mechanism. In methanol, hydrogen peroxide, and catalytic sulfuric acid, the carbonyl oxygen is protonated (14), after which hydrogen peroxide adds as a nucleophile to the carbonyl carbon, forming a tetrahedral intermediate (15). Following an intramolecular proton transfer (16,17), the tetrahedral intermediate collapses, [1,2]-aryl migration occurs, and water is eliminated (18). Nucleophilic addition of methanol to the carbonyl carbon forms another tetrahedral intermediate (19). Following a second intramolecular proton transfer (20,21), the tetrahedral intermediate collapses, eliminating a phenol and forming an ester protonated at the carbonyl oxygen (22). Finally, deprotonation of the carbonyl oxygen yields the collected products and regenerates the acid catalyst (23).
Boric acid-catalyzed Dakin oxidation
Adding boric acid to the acid-catalyzed reaction mixture increases the yield of phenol product over phenyl carboxylic acid product, even when using phenyl aldehyde or ketone reactants with electron-donating groups meta to the carbonyl group or electron-withdrawing groups ortho or para to the carbonyl group. Boric acid and hydrogen peroxide form a complex in solution that, once added to the carbonyl carbon, favors aryl migration over hydrogen migration, maximizing the yield of phenol and reducing the yield of phenyl carboxylic acid.
Methyltrioxorhenium-catalyzed Dakin oxidation
Using an ionic liquid solvent with catalytic methyltrioxorhenium (MTO) dramatically accelerates Dakin oxidation. MTO forms a complex with hydrogen peroxide that increases the rate of addition of hydrogen peroxide to the carbonyl carbon. MTO does not, however, change the relative yields of phenol and phenyl carboxylic acid products.
Urea-catalyzed Dakin oxidation
Mixing urea and hydrogen peroxide yields urea-hydrogen peroxide complex (UHC). Adding dry UHC to solventless phenyl aldehyde or ketone also accelerates Dakin oxidation. Like MTO, UHP increases the rate of nucleophilic addition of hydrogen peroxide. But unlike the MTO-catalyzed variant, the urea-catalyzed variant does not produce potentially toxic heavy metal waste.
The Dakin oxidation is most commonly used to synthesize benzenediols and alkoxyphenols. Catechol, for example, is synthesized from o-hydroxy and o-alkoxy phenyl aldehydes and ketones, and is used as the starting material for synthesis of several compounds, including the catecholamines, catecholamine derivatives, and 4-tert-butylcatechol, a common antioxidant and polymerization inhibitor. Other synthetically useful products of the Dakin oxidation include guaiacol, a precursor of several flavorants; hydroquinone, a common photograph-developing agent; and 2-tert-butyl-4-hydroxyanisole and 3-tert-butyl-4-hydroxyanisole, two antioxidants commonly used to preserve packaged food. In addition, the Dakin oxidation is useful in the synthesis of indolequinones, naturally-occurring compounds that exhibit high anti-biotic, anti-fungal, and anti-tumor activities.
- Baeyer-Villiger oxidation
- Beckmann rearrangement
- Nucleophilic acyl substitution
- Reimer-Tiemann reaction
- Dakin, H.D. (1909). "The oxidation of hydroxy derivatives of benzaldehyde, acetophenone, and related substances". American Chemical Journal 42 (6): 477–498.
- Hocking, M. B.; Bhandari, K.; Shell, B.; Smyth, T. A. (1982). "Steric and pH effects on the rate of Dakin oxidation of acylphenols". The Journal of Organic Chemistry 47 (22): 4208. doi:10.1021/jo00143a007.
- Varma, R. S.; Naicker, K. P. (1999). "The Urea−Hydrogen Peroxide Complex: Solid-State Oxidative Protocols for Hydroxylated Aldehydes and Ketones (Dakin Reaction), Nitriles, Sulfides, and Nitrogen Heterocycles". Organic Letters 1 (2): 189. doi:10.1021/ol990522n.
- Matsumoto, M.; Kobayashi, K.; Hotta, Y. (1984). "Acid-catalyzed oxidation of benzaldehydes to phenols by hydrogen peroxide". The Journal of Organic Chemistry 49 (24): 4740. doi:10.1021/jo00198a037.
- Roy, A.; Reddy, K. R.; Mohanta, P. K.; Ila, H.; Junjappat, H. (1999). "Hydrogen Peroxide/Boric Acid: An Efficient System for Oxidation of Aromatic Aldehydes and Ketones to Phenols". Synthetic Communications 29 (21): 3781. doi:10.1080/00397919908086017.
- Bernini, R., Coratti, A., Provenzano, G., Fibrizi, G., & Tofani, D. (2005). "Oxidation of aromatic aldehydes and ketones by H2O2/CH3ReO3 in ionic liquids: a catalytic efficient reaction to achieve dihydric phenols". Tetrahedron 61: 1821–1825. doi:10.1016/j.tet.2004.12.025.
- Dakin, H.D. (1923). "Catechol". Organic Syntheses 3: 28. doi:10.15227/orgsyn.003.0028.
- Jung, M. E.; Lazarova, T. I. (1997). "Efficient Synthesis of Selectively Protectedl-Dopa Derivatives froml-Tyrosine via Reimer−Tiemann and Dakin Reactions". The Journal of Organic Chemistry 62 (5): 1553. doi:10.1021/jo962099r.
- Alamgir, M., Mitchell, P.S.R., Bowyer, P.K., Kumar, N., & Black, D.S. (2008). "Synthesis of 4,7-indoloquinones from indole-7-carbaldehydes by Dakin oxidation". Tetrahedron 64: 7136–7142. doi:10.1016/j.tet.2008.05.107.