Alkyne Oxidative Dimerization

Alkynes undergo stoichiometric oxidative reactions with Pd(II). A useful reaction is oxidative carboiiyiation. Two types of the oxidative carbonyla-tion of alkynes are known. The first is a synthesis of the alkynic carbox-ylates 524 by oxidative carbonylation of terminal alkynes using PdCN and CuCh in the presence of a base[469], Dropwise addition of alkynes is recommended as a preparative-scale procedure of this reation in order to minimize the oxidative dimerization of alkynes as a competitive reaction[470]. Also efficient carbonylation of terminal alkynes using PdCU, CuCI and LiCi under CO-O2 (1 I) was reported[471]. The reaction has been applied to the synthesis of the carbapenem intermediate 525[472], The steroidal acetylenic ester 526 formed by this reaction undergoes the hydroarylalion of the triple bond (see Chapter 4, Section 1) with aryl iodide and formic acid to give the lactone 527(473],... 

Ammonium cerium(IV) nitrate on reaction with acetone or acetophenone generates acetyl- or benzoylformonitrile oxides, respectively (99). These nitrile oxides dimerize to furoxans and give, in the presence of alkenes and alkynes, 3-acetyl- or 3-benzoyl-4,5-dihydroisoxazoles and 3-acetyl- or 3-benzoylisoxazoles, respectively the yield of the isoxazole derivatives was improved on using ammonium cerium(III) nitrate tetrahydrate-formic acid (99). 

Carbon Dioxide 0=C=0 The reactions of the metallocene sources 1-6 with carbon dioxide depend strongly on the metal and ligands used. Complex 1 gives, by elimination of half of the alkyne, the dimer 93, which forms the titanafuranone 94 after aerial oxidation [49]. 

The alkyne 85 has been oxidatively dimerized with copper(I) salts giving and coupled with l-bromo-2-phenylethyne in the presence of copper (II) salts. The 9-phenacylcarbazole 88 was cleaved to 9-benzylcarbazole with strong aqueous alkali in hot glycol. 

The diyne 20b, prepared by oxidative dimerization of the corresponding terminal alkyne, was cyclized to the biindole 20e using NaOEt. <95SL859> H... 

The precatalyst Cp RuCl(COD) allowed the head-to-head oxidative dimerization of terminal alkynes and the concomitant 1,4-addition of carboxylic acid to stereoselectively afford 1-acyloxy-l,3-dienes in one step under mild conditions [89] (Eqs. 67,68). The first step of the reaction consists in the oxidative head-to-head alkyne coupling via the formation of a ruthenacycle intermediate that behaves as a mixed Fischer-Schrock-type biscarbene ruthenium complex, allowing protonation and nucleophilic addition of the carboxylate. 

The Sonogashira coupling can be considered a special case of catalytic alkyne activation. Interestingly, it is also possible to conduct alkyne activation under oxidative conditions in the presence of Pd catalysts without oxidative dimerization. Here, Costa and coworkers [139] have developed a Pd-catalyzed sequential carboxylation-alkoxycarbonylation of acetylenic amines in the presence of oxygen to give mixtures of Z- and -configurcd 2-oxo-oxazolidin-5-ylidene]-acetic acid methyl ester 193 and 194 in good to excellent yields (Scheme 75). 

A variety of conjugated dienes can be synthesized stereospecifically via the hydroalumination of al-kynes. For example, the first-formed adduct from an alkyne can insert a second mole of alkyne and upon hydrolysis yield the ( , )-1,3-alkadiene (equation 23). Alternatively, the first-formed adduct can directly oxidatively dimerize to the ( , )-1,3-diene (equation 64). ... 

The synthesis of conjugated diynes via the Glaser coupling reaction " is the classical method for homocoupling of terminal alkynes. The coupling reaction is catalyzed by CuCl or Cu(OAc)2 in the presence of an oxidant and ammonium chloride or pyridine to yield symmetrically substituted diynes. " The oxidative dimerization appears to proceed via removal of the acetylenic proton, formation of an alkynyl radical, and its dimerization. 

Hydrosilations of dienes and alkynes have been studied, and in both cases single and double silylations are possible. For 1,3-dienes, both 1,2 and 1,4 addition products can be observed8,195 213 271-272. A Ziegler-type catalyst composed of nickel(II) pentadienoate and triethylaluminum is active in hydrosilylation of terminal alkynes, but this reaction is accompanied by oxidative dimerization of the alkyne (equation 101). The major product in most cases was the head-to-head dimer273. 

Aryl and alkyl-substituted diynes and tetraynes have been synthesized in good yields (82-99%) by TBAF-promoted desily-lation and Cu-catalyzed oxidative dimerization of triisopropylsi-lyl (TlPS)-protected acetylenes (eq 38). Copper acetate was used as oxidant in this reaction. Aryl- and alkenyl alkynes were made under similar conditions (eq 39). Pd/C with TBAF was used in ligand- and copper-free, one-pot, domino Halex-Sono-gashira reactions. Similarly, TBAF promoted the synthesis of 2-substituted indoles by a tandem Sonogashira/cyclization reaction of 2-iodoanilines and terminal alkynes. ... 

Since its discovery, the Songashira reaction has been a valuable tool for the functionalization of aromatic and heteroaromatic halides with the versatile alkyne function [9]. Among the many possible alkyne transformations, these derivatives can undergo cyclization reactions to prepare indoles, benzo- and heteroaryl- furans, and other useful pharmacophores. One of the difficulties of the reaction is the propensity of acetylenes to oxidatively dimerize under the reaction conditions, particularly when the cross-coupling reaction is slow as in the case of aromatic... 

The authors found that the addition of TMEDA before oxidation was necessary to increase both reproducibility and yields of this sequential process, presumably due to the inhibition of the oxidative dimerization [98], a side reaction known in the chemistry of organocopper compounds. Alkynes with electron-withdrawing groups directly bound to the sp carbon were also employed in the stereoselective carbocupration [99]. For example, the carbocupration of alkynoates 341 promoted by Lewis acids, such as trimethylsilyl triflate, leads to the isomeric TMS-allenoate compounds, which on hydrolysis or a Mukaiyama-type aldol reaction produce the corresponding di- and trisubstituted acrylates 342 (Scheme 10.116) [100]. 

Unlike the cases of alkenes, Wacker-type intermolecular oxypalladation reactions of alkynes have not been extensively investigated, although their intramolecular cyclization reactions have been developed into synthetically useful procedures (Sects. V3.2). In principle, they can proceed by a few alternative paths shown for the cases of terminal alkynes in Scheme 14. In reality, however, alkynyl C—H activation by Pd to give alkynylpalladium derivatives shown in Scheme 3 may well be the dominant path, as suggested by the carbonylative oxidation of terminal alkynes to give alkynoic acid esters shown in Scheme 15. Oxidative dimerization of alkynes is a potentially serious side reaction. Further systematic investigation of this fundamentally important process appears to be highly desirable. 

Catalytic carbopalladation is a ubiquitous process and alkynes are viable substrates. Alkenyl tellurides couple efficiently with alkynes with retention of the double bond geometry. Relatively large amounts of palladium catalyst are required.Oxidative dimerization of monoterpenes has been assumed to involve alkenylpalladium(ii) intermediates. Alkenylpalladium(ii) and di(alkenyl)palladium(iv) complexes have been put forward as intermediates in a similar reaction of halogenoterpenes. The subject has been reviewed concerning the formation of heterocycles by intramolecular cyclization of intermediate alkenylpalladium intermediates. ... 

The heterogeneous catalytic system iron phthalocyanine (7) immobilized on silica and tert-butyl hydroperoxide, TBHP, has been proposed for allylic oxidation reactions (10). This catalytic system has shown good activity in the oxidation of 2,3,6-trimethylphenol for the production of 1,4-trimethylbenzoquinone (yield > 80%), a vitamin E precursor (11), and in the oxidation of alkynes and propargylic alcohols to a,p-acetylenic ketones (yields > 60%) (12). A 43% yield of 2-cyclohexen-l-one was obtained (10) over the p-oxo dimeric form of iron tetrasulfophthalocyanine (7a) immobilized on silica using TBHP as oxidant and CH3CN as solvent however, the catalyst deactivated under reaction conditions. 

The higher catalytic activity of the cluster compound [Pd4(dppm)4(H2)](BPh4)2 [21] (20 in Scheme 4.12) in DMF with respect to less coordinating solvents (e.g., THF, acetone, acetonitrile), combined with a kinetic analysis, led to the mechanism depicted in Scheme 4.12. Initially, 20 dissociates into the less sterically demanding d9-d9 solvento-dimer 21, which is the active catalyst An alkyne molecule then inserts into the Pd-Pd bond to yield 22 and, after migratory insertion into the Pd-H bond, the d9-d9 intermediate 23 forms. Now, H2 can oxidatively add to 23 giving rise to 24 which, upon reductive elimination, results in the formation of the alkene and regenerates 21. 

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