Alkyl halides, 787 dehydrogenation reactions

A gold monohydride species was also suggested in the report by Ito and Sawamura et al. on the dehydrogenative silylation of alcohols by HSiEt3 and a diphosphine gold(I) complex. Reaction was selective for the silylation of hydroxy groups in the presence of alkyl halides, ketones, aldehydes, alkenes, alkynes and other functional groups [193]. 

Bamford-Stevens reaction of the tosylhydrazones of the readily available tetrahydrofuran-3-ones provides a useful synthesis of 2,3-dihydrofurans which may be dehydrogenated to furans with 2,3-dichloro-5,6-dicyano-l,4-benzoquinone (66CJC1083). Tetrahydrofuran-2-ones (y-butyrolactones) may be alkylated in the 3-position with LDA and an alkyl halide. The products on reaction with phenyl selenylchloride and LDA, and subsequent oxidation, yield 3-alkylfuran-2(5//)-ones reducible with DIBAL to furans (75JOC542). 

Triphenylsilyl ethers are typically prepared by the reaction of the alcohol with triphenylsilyl chloride (mp 92-94 °C) and imidazole in DMF at room temperature. The dehydrogenative silylation of alcohols can be accomplished with as little as 2 mol% of the commercial Lewis acid tris(pentaf1uorophenyl)borane and a silane such as triphenylsilane or triethylsilane [Scheme 4.98]. Primary, secondary, tertiary and phenolic hydroxyls participate whereas alkenes, alkynes, alkyl halides, nitro compounds, methyl and benzyl ethers, esters and lactones are inert under the conditions. The stability of ether functions depends on the substrate. Thus, tetrahydrofurans appear to be inert whereas epoxides undergo ring cleavage. 1,2- and 1,3-Diols can also be converted to their silylene counterparts as illustrated by the conversion 983 98.4. Hindered silanes such as tri-... 

In the dehydrogenation of alcohols, Co " ions also increase the selectivity of the reaction. Alkaline earth metal oxides are good catalysts for the dehydrohalogenation of alkyl halides at 100-250 °C. The elimination of hydrogen halide proceeds by a highly selective E2 reaction. The following selectivity series was found for the tnms elimination ... 

The synthesis of a-acyloxy ethers (formation of C—O bonds) was achieved by the TBHP oxidation of a mixture of a carboxylic acid (R C02H, R =aryl, heteroaryl, alkyl) and an ether (R, R = alkyl, alkyl halide) in the presence of BU4NI as the catalyst. The transformation involved a cross-dehydrogenative coupling (CDC) reaction of the C-H bond. ... 

Regiochemical synthesis of 1-substituted imidazole-4-carboxylates can be achieved by treatment of a (Z)-)3-dimethylamino-of-isocyanoacrylate with an alkyl or acyl halide (see Section 2.1.1 and Scheme 2.1.8), by cyclization of 3-alkylamino-2-aminopropanoic acids with triethyl orthoformate followed by dehydrogenation of the initially formed imidazoline (see Section 3.1.1 and Scheme 3.1.2), by condensation of 3-arylamino-2-nitro-2-enones with ortho esters in the presence of reducing agents (see Section 3.1.1 and Scheme 3.1.4), by reaction of an alkyl A -cyanoalkylimidate with a primary amine (see Section 3.2 and Scheme 3.2.1), the poor-yielding acid-catalysed cyclization of a 2-azabutadiene with a primary amine (see Section 3.2 and Scheme 3.2.3), the cyclocondensation of an isothiourea with the enolate form of ethyl isocyanoacetate (see Section 4.2 and Scheme 4.2.5), and from the interaction of of-aminonitrile, primary tunine and triethyl orthoformate (see Chapter 5, Scheme 5.1.5, and Tables 5.1.1 and 5.1.2). 

Typical base-catalysed reactions that occur over alkali metal-exchanged zeolites include dehydrogenations, double bond isomerisations, side-chain alkylation of aromatics, conversion of methyl halides and a range of condensations. The reaction of alcohols over zeolites can be used to determine whether acid or base catalysis predominates. Whereas acid forms of zeolites catalyse dehydrations, leading to alkenes and the products of their subsequent reactions, basic sites catalyse dehydrogenations, leading to aldehydes and ketones. 

The alcohol-alcohol coupling reaction involves the following steps (Schemes 3, 4) (1) the initial simultaneous transition-metal-catalyzed dehydrogenation of the two different alcohols to afford the corresponding carbonyl compounds and metal halide and (2) the aldol condensation of the carbonyl compounds and the subsequent hydrogenation of the resulting unsaturated carbonyl compounds in a similar manner to that described above for the ketone a-alkylation reaction (Schemes 3, 4) to give the C-alkylated ketone product. 

Abstract The selective catalytic activation/functionalization of sp C-H bonds is expected to improve synthesis methods by better step number and atom economy. This chapter describes the recent achievements of ruthenium(II) catalysed transformations of sp C-H bonds for cross-coupled C-C bond formation. First arylation and heteroarylation with aromatic halides of a variety of (hetero)arenes, that are directed at ortho position by heterocycle or imine groups, are presented. The role of carboxylate partners is shown for Ru(II) catalysts that are able to operate profitably in water and to selectively produce diarylated or monoarylated products. The alkylation of (hetero)arenes with primary and secondary alkylhalides, and by hydroarylation of alkene C=C bonds is presented. The recent access to functional alkenes via oxidative dehydrogenative functionalization of C-H bonds with alkenes first, and then with alkynes, is shown to be catalysed by a Ru(ll) species associated with a silver salt in the presence of an oxidant such as Cu(OAc)2. Finally the catalytic oxidative annulations with alkynes to rapidly form a variety of heterocycles are described by initial activation of C-H followed by that of N-H or O-H bonds and by formation of a second C-C bond on reaction with C=0, C=N, and sp C-H bonds. Most catalytic cycles leading from C-H to C-C bond are discussed. 

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