Primary alcohols palladium chloride

Abnormal olefin arylation reactions which are of interest mechanistically and preparatively occur with some allylically substituted compounds. The ailylic esters and ethers appear normal and produce cinnamyl derivatives exclusively while ailylic alcohols and chlorides are abnormal. Ailylic alcohols and "arylpalladium acetates form 3-arylaldehydes from primary ailylic alcohols and 3-arylketones from secondary alcohols 3°). The mechanism of reaction apparently involves anti-Markovnikov addition of the palladium compound to the double bond followed by elimination of the hydrogen atom on the hydroxyl-bearing carbon rather than the benzylic hydrogen. This again would be elimination of the more electronegative hydrogen atom. 

A few type la reductive cycUzations leading to indoles have been reported. A palladium (II) trifluoroacetate catalyst was effective in the reductive cyclization of orfho-nitrostyrenes to 2-substituted indoles <05T6425>. The Batcho-Leimgruber indole synthesis, the reductive cyclization of p-amino-2-nitrostyrenes, was utilized in a synthesis of 5-formylindole <05JHC137>. A partial reduction of a nitroarene provided a route to iV-hydroxyindoles <05AG(E)3736>. Treatment of nitro ketoester 90 with tin chloride in the presence of a primary alcohol nucleophile provided Al-hydroxyindole 93 via hydroxylamine intermediate 91. 

Alexander Mikhaylovich Saytzev (Saytzeff) (Kazan 20 June 1841 (O.S.)-2 September 1910) studied with Kolbe in Marburg and Leipzig, and was professor in the University of Kazan. He discovered the synthesis of primary and secondary alcohols from esters, ketones, and aldehydes by the action of zinc and alkyl iodides (see Reformatsky, p. 858). He also discovered aliphatic sulphoxides. His brother Mikhayl Mikhaylovich (b. Kazan, 30 August 1845), at first his assistant and later manager of a chemical works in Kazan, discovered the reduction of acid chlorides to aldehydes by hydrogen gas in presence of palladium. ... 

An interesting synthesis of J -butenolides (28) via carbonylation of vinyl-mercurials (27) has been reported. This palladium-catalysed conversion goes in virtually quantitative yield, but its synthetic utility is limited by the availability of the /ra/i5-chlorovinylmercurials (27). These compounds were synthesized from the corresponding acetylenic alcohol by reaction with mercuric chloride-sodium chloride, but yields were generally low (ca. 30%) and the reaction appears to be limited to primary and tertiary acetylenic alcohols. 

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