Dehydration pinacol rearrangement

The pinacol rearrangement is a dehydration reaction that converts a 1,2-diol into a ketone. The reaction involves two carbocation intermediates. 

Dehydration of diols pinacol rearrangement. Preparation of pinacolone... 

Pinacol rearrangement is a dehydration of a 1,2-diol to form a ketone. 2,3-drmethyl-2,3-butanediol has the common name pinacol (a symmetrical diol). When it is treated with strong acid, e.g. H2SO4, it gives 3,3-dimethyl-2-butanone (methyl r-butyl ketone), also commonly known as pinacolone. The product results from the loss of water and molecular rearrangement. In the rearrangement of pinacol equivalent carbocations are formed no matter which hydroxyl group is protonated and leaves. 

The pinacol rearrangement is a dehydration of an alcohol that results in an unexpected product. When hot sulfuric acid is added to an alcohol, the expected product of dehydration is an alkene. However, if the alcohol is a vicinal diol, the product will be a ketone or aldehyde. The reaction follows the mechanism shown, below. The first hydroxyl group is protonated and removed by the acid to form a carboca-tion in an expected dehydration step. Now, a methyl group may move to fonn an even more stable carbocation. This new carbocation exhibits resonance as shown. Resonance Structure 2 is favored because all tire atoms have an octet of electrons. The water deprotonates Resonance Structure 2, forming pinacolone and regenerating the acid catalyst. 

Pinacol and other highly substituted 1,2-diols tend to undergo dehydration with rearrangement under acid-catalysis. 

Using our knowledge of alcohol reactions, we can explain results that seem strange at first glance. The following dehydration is an example of the pinacol rearrangement ... 

Hydride Reduction of a Carbonyl Group 454 Reaction of a Tertiary Alcohol with HBr(S[ 1) 480 Reaction of a Primary Alcohol with HBr (SN2) 480 Reaction of Alcohols with PBr3 485 (Review) Acid-Catalyzed Dehydration of an Alcohol 487 The Pinacol Rearrangement 495 Cleavage of an Ether by HBr or HI 639 Acid-Catalyzed Opening of Epoxides in Water 649 Acid-Catalyzed Opening of an Epoxide in an Alcohol Solution 650... 

Acid Form - Pseudoliquid Phase Behavior. Owing to a high affinity for polar molecules, large quantities of molecules such as alcohols and ether are absorbed within the bulk phase of crystalline heteropolyacids. The amounts of pyridine, methanol, and 2-propanol absorbed correspond to 50-100 times that which can be adsorbed on the surface, while nonpolar molecules like ethylene and benzene are adsorbed at the surface only. Catalytic reactions of polar molecules occiu both on the surface and in the bulk, so that the solid heteropolyacid behaves as a highly concentrated solution, called a pseudoliquid phase . The dehydration of alcohols, various conversions of methanol and dimethyl ether to hydrocarbons in gas-solid systems, and the alkylation of phenol and pinacol rearrangements can all occur in the pseudoliquid. The transient response using isotopically labeled 2-propanol provides evidence for the pseudoliquid phase behavior of H3PW12O40. This behavior influences the selectivity, for example, the aUcene/aUcane ratio, in the conversion of dimethyl ether. 

Oxiranes cannot be prepared directly from 1,2-diols by dehydration. Formation of the oxirane intermediate has been studied in connection with the mechanism of the pinacolic rearrangement. Oxiranes can be prepared stereoselectively from the acetals and ketals of 1,2-diols. D-(+)-2,3-epoxybutane has been obtained from an optically active diol via conversion of the ketal 64 to a halohydrin ester (Eq. 52). ... 

As catalytic tests four reactions, isomerization of 1-butene and methyloxirane, dehydration of 2-propanol and the pinacol rearrangement of 2,3-dimethyl-2,3-butanediol were used. 

The Prins-pinacol rearrangement was utilized during the first enantioselective total synthesis of briarellin diterpenes by L.E. Overman and co-workers. The cyclohexadienyl diol substrate was condensed with a (Z)-a,p-unsaturated aldehyde at low temperature in the presence of catalytic amounts of acid and MgS04 as dehydrating agent. The initially formed acetal was then exposed to 10 mol% of SnCU to afford the desired tetrahydroisobenzofuran as a single stereoisomer that was later converted to briarellin F. 

Pocker, Y., Ronald, B. P. Kinetics and mechanism of vic-diol dehydration. II. p-Anisyl group in pinacolic rearrangement. J. Org. Chem. 

Aqueous or concentrated acids are the most commonly used catalysts, but several other acidic materials can cause pinacol rearrangement, as noted in a recent review of the dehydration reactions of diols. 

As with polystyrene sulfonic resins, Nafion-based acid catalysts are highly efficient for hydration and dehydration processes and, in general, for condensation reactions that occur with the formation of water or similar secondary products. Formation of ethers has been studied for various alcohols [109-111]. Dehydration of 1,4- and 1,5-diols at 135 °C affords the corresponding cyclic ethers such as 20 in excellent yields (Scheme 10.7), while 1,3-diols experience different transformations depending on their structure [112]. The dehydration of 1,2-diols mainly proceeds via the pinacol rearrangement. Further condensation of the initially formed carbonyl compound and unreacted diol affords 1,3-dioxolanes [113]. The catalyst could be efficiently reused following a reactivation protocol. Formation of aryl ethers is also possible, and the synthesis of dibenzofurans 21 (X = O) from 2,2 -dihydroxybiphenyls has been reported (Scheme 10.7) [114]. The related reaction... 

Dehydration is the first step of pinacol rearrangement of vzc-diol. Tertiary alcohols can dehydrate intramolecularly with an acid as a catalyst to form olefins, which provides another mechanism of a reverse polarity change from a polar to nonpolar state [353]. 

The pinacol rearrangement was first described by Fittig in 1860 [10]-treatment of pinacol (2,3-dimethyl-2,3-butanediol, 1), a ditertiary 1,2-diol, with sulfuric acid resulted in the formation of pinacolone (3,3-dimethyl-2-butanone, 2) (Scheme 1). The overall reaction is dehydration with concomitant migration of a methyl substituent. 

When aromatic pinacols are reacted with an acid, products often arise from dehydration and rearrangement.5 This general conversion is known as the pinacol rearrangement. The pinacol rearrangement may be promoted by both Brdnsted and Lewis acids.6 In the procedure described here, superacidic triflic acid is reacted with an aryl pinacol and a dehydrative cyclization occurs to give the substituted phenanthrene product. Related to this conversion, the chemistry of benzopinacol in sulfuric acid and triflic acid is contrasted in Scheme 1. We have proposed that the superacidic triflic acid causes the formation of diprotonated intermediates which promote the dehydrative cyclization.4... 

A vicinal diol has OH groups on adjacent carbons. The dehydration of a vicinal diol is accompanied by a rearrangement called the pinacol rearrangement. Propose a mechanism for this reaction. 

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