Catalytic reactions ketone rearrangement

In fluorinated alcohol solvents, nonstrained ketones such as cyclohexanone (1) undergo oxidation to lactones in the presence of hydrogen peroxide and catalytic amounts of Brpnsted acids (Berkessel and An-dreae 2001 Berkessel et al. 2002). Unlike the classical Baeyer-Villiger reaction, ketone oxidation with H2O2 in e.g. HFIP proceeds via a spiro-bisperoxide 2 intermediate (Scheme 1). In contrast to other solvents, the acid-catalyzed rearrangement of the spiro-bisperoxide 2 to two equivalents of the product lactone 3 proceeds rapidly and cleanly in HFIP. Preliminary calculations indicate active participation of the fluorinated alcohol solvent in the rate-determining step also in this case. 

Abstract The use of organoaluminum-based Lewis acids (A1R X3 R = alkyl, alkynyl, X = halide or pseudohalide) in the period 2000 to mid-2011 is overviewed with a focus on (1) stoichiometric reactions in which one of the organoaluminum substituents is transferred to the substrate (e.g., the opening of epoxides, 1,2-additions to carbonyl compounds, coupling with C-X, and Reissert chemistry) and (2) asymmetric, often catalytic, reactions promoted by Lewis acid catalysts derived from organoaluminum species (e.g., use of auxiliaries with alanes, Diels-Alder, and related cycloaddition reactions, additions to aldehydes and ketones, and skeletal rearrangement reactions). 

Finally a general approach to synthesize A -pyrrolines must be mentioned. This is tl acid-catalyzed (NH4CI or catalytic amounts of HBr) and thermally (150°C) induced tea rangement of cyclopropyl imines. These educts may be obtained from commercial cyan> acetate, cyclopropyl cyanide, or benzyl cyanide derivatives by the routes outlined below. Tl rearrangement is reminiscent of the rearrangement of 1-silyloxy-l-vinylcyclopropancs (p. 7 83) but since it is acid-catalyzed it occurs at much lower temperatures. A -Pyrrolines constitut reactive enamines and may be used in further addition reactions such as the Robinson anei lation with methyl vinyl ketone (R.V. Stevens, 1967, 1968, 1971). 

Catalytic reduction of codeine (2) affords the analgesic dihydrocodeine (7) Oxidation of the alcohol at 6 by means of the Oppenauer reaction gives hydrocodone (9)an agent once used extensively as an antitussive. It is of note that treatment of codeine under strongly acidic conditions similarly affords hydrocodone by a very unusual rearrangement of an allyl alcohol to the corresponding enol, followed by ketonization. 

The Beckmann rearrangement of oximes to produce amides is promoted by perrhenate ions under phase-transfer catalytic conditions, in the presence of trifluoro-methanesulphonic acid in nitromethane [6]. Under these conditions, the rearrangement reaction is frequently accompanied by the solvolysis of the oxime to the ketone. This can be obviated by the addition of hydroxylamine hydrochloride. No reaction occurs in the absence of the ammonium catalyst or with the O-acetyl oximes. 

Apart from the reaction of cyclohexanecarboxylic acid with methyllithium, cyclohexyl methyl ketone has been prepared by the reaction of cyclohexylmagnesium halides with acetyl chloride or acetic anhydride and by the reaction of methylmagnesium iodide with cyclohexanecarboxylic acid chloride. Other preparative methods include the aluminum chloride-catalyzed acetylation of cyclohexene in the presence of cyclohexane, the oxidation of cyclohexylmethylcarbinol, " the decarboxylation and rearrangement of the glycidic ester derived from cyclohexanone and M)utyl a-chloroj)ropionate, and the catalytic hydrogenation of 1-acetylcycIohexene. "... 

Electrochemical oxidation of epoxides in absence of nucleophiles, catalyses a rearrangement to the carbonyl compound. The electrolyte for this process is dichlo-romethane with tetrabutylammonium perchlorate. Reaction, illustrated in Scheme 8.7, involves the initial formation of a radical-cation, then rearrangement to the ketone radical-cation, which oxidises a molecule of the substrate epoxide. The process is catalytic and requires only a small charge of electricity [73]. 

Figure 7-11 shows a Friedel-Crafts acylation reaction. The reaction produces an aryl ketone, which is useful in synthesis because it makes it relatively easy to convert the ketone (RCOR) group to an alkyl (R) group. The procedure involves the catalytic hydrogenation of the aryl ketone, and it s particularly useful when the electrophile in a Friedel-Crafts alkylation is susceptible to rearrangement. 

A vicinal diol 1, when treated with a catalytic amount of acid, can rearrange to give an aldehyde or ketone 3 by migration of an alkyl or aryl group. The prototype of this reaction is the rearrangement of pinacol (R = r2 = = r4 = CH3) to... 

An a-diazo ketone 1 can decompose to give a ketocarbene, which further reacts by migration of a group R to yield a ketene 2. Reaction of ketene 2 with water results in formation of a carboxyhc acid 3. The Woljf rearrangement is one step of the Arndt-Eistert reaction. Decomposition of diazo ketone 1 can be accomplished thermally, photochemically or catalytically as catalyst amorphous silver oxide is commonly used ... 

Trust s group has shown that another selective reaction involving C—O bond formation followed by rearrangement and C—C bond formation occurred when Cp-containing ruthenium complexes were used as catalytic precursors. With RuCl(Cp)(PPh3)2 in the presence of NH4PF6, an additive known to facilitate chloride abstraction from the metal center, the addition of allylic alcohols to terminal alkynes afforded unsaturated ketones [46, 47]. It has been shown that the key steps are the... 

One of the achievements in Baeyer-Villiger oxidation is aerobic catalytic rearrangement of cyclic ketones, for example, / -butylcyclohexanone, in the presence of Ru02 or Mn02 (0.05 equiv) and benzaldehyde (3 equiv) at room temperature (Equation 32), giving the respective e-caprolactones in yields up to 95%, the reaction being accelerated in the presence of lithium perchlorate <1994SL1037>. 

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