Alcohols overoxidation

This example shows that overoxidation of allylic alcohols may occur with DDQ. ... 

Oxidation of primary alcohols to aldehydes (Section 15.10) Pyridinium dichromate (PDC) or pyridinium chloro-chromate (PCC) in anhydrous media such as dichloromethane oxidizes primary alcohols to aldehydes while avoiding overoxidation to carboxylic acids. 

DDQ is often used to remove the MPM group from alcohols and can be used to cleave it from an amine, but in the following case overoxidation also occurs ... 

Reactions with other nucleophiles follow a similar mechanism. For the reaction of Cl with poly(3-methylthiophene) in acetonitrile, the reaction stops at structure 5 (Scheme 2).128 A fully conjugated, Cl-substi-tuted product 6 can subsequently be obtained by electrochemical or chemical dehydrogenation.128 With Br and alcohols, the overoxidation... 

Various experimental conditions have been used for oxidations of alcohols by Cr(VI) on a laboratory scale, and several examples are shown in Scheme 12.1. Entry 1 is an example of oxidation of a primary alcohol to an aldehyde. The propanal is distilled from the reaction mixture as oxidation proceeds, which minimizes overoxidation. For secondary alcohols, oxidation can be done by addition of an acidic aqueous solution containing chromic acid (known as Jones reagent) to an acetone solution of the alcohol. Oxidation normally occurs rapidly, and overoxidation is minimal. In acetone solution, the reduced chromium salts precipitate and the reaction solution can be decanted. Entries 2 to 4 in Scheme 12.1 are examples of this method. 

A photo-induced dihydroxylation of methacryamide by chromium (VI) reagent in aqueous solution was recently reported and may have potential synthetic applications in the syn-dihydroxylation of electron-deficient olefins.63 Recently, Minato et al. demonstrated that K3Fe(CN)6 in the presence of K2C03 in aqueous rm-butyl alcohol provides a powerful system for the osmium-catalyzed dihydroxylation of olefins.64 This combination overcomes the disadvantages of overoxidation and low reactivity on hindered olefins related to previous processes (Eq. 3.14). 

Izumi and Urabe [105] found first that POM compounds could be entrapped strongly on active carbons. The supported POMs catalyzed etherization of ferf-butanol and n-butanol, esterification of acetic acid with ethanol, alkylation of benzene, and dehydration of 2-propanol [105], In 1991, Neumann and Levin [108] reported the oxidation of benzylic alcohols and amines catalyzed by the neutral salt of Na5[PV2Mo10O40] impregnated on active carbon. Benzyl alcohols were oxidized efficiently to the corresponding benzaldehydes without overoxidation ... 

An alternative approach consisted of the use of an alcohol as aldehyde precursor since aldehydes are less stable (prone to overoxidation, polymerization or formation... 

Good selectivity for the oxidation of primary alcohols in the presence of secondary ones can be achieved. By appropriate choice of the reaction conditions, overoxidation of the aldehyde from a primary alcohol to carboxylic acid can be minimized. Kinetic isotope effects in the range of 2 to 3 testify about the relevance of the H+-elimination step upon the overall reactivity . In general, the efficiency of oxidation of alkanols is slightly lower... 

NaClO, or else in the two-phase system but with a quaternary ammonium (viz. AUquat) ion as a phase-transfer catalyst, overoxidation to the corresponding carboxylic acid is obtained (entry 4). Therefore, by proper choice of the experimental conditions, a synthetically useful distinction in products formation can be made for the oxidation of primary alcohols, even though we are far from a satisfactory understanding of the reason behind this different behaviour. In fact TEMPO, as a well-known inhibitor of free-radical processes is allegedly responsible for the lack of overoxidation of an aldehyde to carboxylic acid (entry 3) this notwithstanding, TEMPO is also present under those conditions where the overoxidation does occur (eutry 4). Moreover, a commou teuet is that the formation of the hydrated form of an aldehyde (in water solution) prevents further oxidation to the carboxylic acid however, both entries 3 and 4 refer to water-organic solutions, and their... 

The most profitable is certainly the use of laccase (Lc) with TEMPO. It enables the almost quantitative conversion of primary benzylic and allylic alcohols to aldehydes without overoxidation under mild conditions (Table 14, entries 1 and 2), that is, 25 °C and pH = 4.5 in the presence of atmospheric O2, for a reaction time of 24 h. The successful enzyme is the one obtained from the fungus Trametes villosa. 

Primary benzylic alcohols are oxidized to aldehydes in good yields without overoxidation (entry 1) lowering the pH from 5 to 3.5 increases the conversion, for reasons not fnUy understood yet (entry 2) . The aminoxyl radical is an electrophilic species" ... 

By suitable modification of reaction conditions, it was found possible to reduce 859 to keto alcohol 873 K The subsequent conversion of this intermediate to 874 proceeded without event. However, 874 could not be oxidized to aldehyde 875. Overoxidation to produce 876 or 877 (Jones conditions) invariably was observed due to the extreme sensitivity of874. This potentially expedient route to dodecahedrane therefore had to be abandoned and recourse made to blocking group methodology. 

Taylor and Flood could show that polystyrene-bound phenylselenic acid in the presence of TBHP can catalyze the oxidation of benzylic alcohols to ketones or aldehydes in a biphasic system (polymer-TBHP/alcohol in CCI4) in good yields (69-100%) (Scheme 117) °. No overoxidation of aldehydes to carboxylic acids was observed and unactivated allylic alcohols or aliphatic alcohols were unreactive under these conditions. In 1999, Berkessel and Sklorz presented a manganese-catalyzed method for the oxidation of primary and secondary alcohols to the corresponding carboxylic acids and ketones (Scheme 118). The authors employed the Mn-tmtacn complex (Mn/168a) in the presence of sodium ascorbate as very efficient cocatalyst and 30% H2O2 as oxidant to oxidize 1-butanol to butyric acid and 2-pentanol to 2-pentanone in yields of 90% and 97%, respectively. This catalytic system shows very good catalytic activity, as can be seen from the fact that for the oxidation of 2-pentanol as little as 0.03% of the catalyst is necessary to obtain the ketone in excellent yield. 

To prevent overoxidation of aldehydes, the very mild oxidant dimethyl sulfoxide or dmso, is used to react with T halides or sulfonates to give aldehydes. These reactants are in the same oxidation level as alcohols ... 

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