Oxidative coupling copper® bromide

Compounds with a terminal acetylenic function, RCsCH, react with 1-bromoalkynes, R CsCBr in the presence of an aliphatic amine and a catalytic amount of a copper salt to give the coupling products RCsCCsCR. This useful reaction, discovered by Cadiot and Chodkiewicz [195], gives a ready access to a number of poly-unsaturated systems. The usual procedure involves dropwise addition of the bromoacetylene R GsCBr to a mixture of the acetylene RCsCH, ethylamine, ethanol or methanol, a catalytic amount of copper chloride or bromide and a small amount of hydroxylamine.HCl. This reducing agent prevents the oxidation to copper ). The reaction is usually very fast at temperatures in the region of 30 C. Since much heat is evolved, the reaction can be monitored easily by temperature observation. 

In addition to reactions initiated with copper metal, reactions have been conducted with copper salts, such as copper oxides, alloys and coordination complexes. Reactions with many bases in several polar solvents have also been explored. Diphenylamine and o-bromonitrobenzene couple with stoichiometric amounts of copper(I) oxide and copper(I) bromide in DMA (equation 59)234. The synthesis of triaryl amines from aryl iodides and arylamines in one-pot proceeds in the presence of Cul and potassium tart-butoxide at 135 °C235. The highest yields were obtained with aryl iodides and electron-rich arylamines. 

Aryltrimethyl- or tri- -butylstaimanes as common Stille reagents are also successfully homo-coupled under palladium catalysed reactions in the presence of ethyl 2,3-dibromophenylpropionate (443) [26], or more conveniently by oxidation with copper(I) salts, e.g. CuCl [27], or copper(II) salts, e.g. Cu(N03)2 3H20 [28,29], which proceed smoothly at room temperature in tetrahydrofuran or DMF to afford symmetrical biaryls in excellent 3uelds. The Cu(N03)2-mediated homo-coupling works well also with diaryldimethyl(or -butyl)stannanes [30]. Moreover, the reaction can be accomplished with a catalytic amount of copper(II) chloride or manganese(II) bromide (10 mol%) in the presence of iodine as stoichiometric oxidant [31]. For example, compound 443, acting as an oxidant, converts the phenyltri-n-butylstannane (184) to biphenyl (8) in 86% yield [26], Scheme 11. 

Tri- and tetra-substituted dihydropyranones and furanones have also been synthesized by a Wacker/Mizoroki-Heck domino process (Scheme 8.72). Gouvemeur and cowoikers [151] very recently prepared these kinds of compounds using different palladium sources, copper acetate as redox mediator, oxygen as oxidant and lithium bromide as additive. The coupling of two electron-poor substrates, ethyl acrylate and -hydroxy alkynones 294, led to the desired compounds 295a-e in moderate yields. 

Enol Ether Synthesis. A 2-(trimethylsilyl)ethyl-based dithioorthoformate was prepared via copper(II) bromide-promoted oxidative coupling of bis(phenylthio)-methyltributylstannane. The dithioorthoformate thus prepared is treated with a titanocene(II) reagent followed by the addition of ketones or esters to promote alkoxymethylidenation as exemplified in eq 32. ... 

The oxidative coupling of benzothiazoles with azine JV-oxides is promoted by catalytic Pd(OAc)2 and CuBr and stoichiometric Cu(OPiv)2 (eq 142). The copper pivalate salt plays a dual role oxidant and concerted metalation-deprotonation (CMD) promoter, while the role of copper bromide is less obvious. 

Secondary bromides and tosylates react with inversion of stereochemistry, as in the classical SN2 substitution reaction.24 Alkyl iodides, however, lead to racemized product. Aryl and alkenyl halides are reactive, even though the direct displacement mechanism is not feasible. For these halides, the overall mechanism probably consists of two steps an oxidative addition to the metal, after which the oxidation state of the copper is +3, followed by combination of two of the groups from the copper. This process, which is very common for transition metal intermediates, is called reductive elimination. The [R 2Cu] species is linear and the oxidative addition takes place perpendicular to this moiety, generating a T-shaped structure. The reductive elimination occurs between adjacent R and R groups, accounting for the absence of R — R coupling product. 

Zinc dust is frequently covered with a thin layer of zinc oxide which deactivates its surface and causes induction periods in reactions with compounds. This disadvantage can be removed by a proper activation of zinc dust immediately prior to use. Such an activation can be achieved by a 3-4-minute contact with very dilute (0.5-2%) hydrochloric acid followed by washing with water, ethanol, acetone and ether [/55]. Similar activation is carried out in situ by a small amount of anhydrous zinc chloride [156 or zinc bromide [157 in alcohol, ether or tetrahydrofuran. Another way of activating zinc dust is by its conversion to a zinc-copper couple by stirring it (180g) with a solution of 1 g of copper sulfate pentahydrate in 35 ml of water [/55]. 

A copper(O) complex, electro-generated from Cu(acac)2, is able to undergo an oxidative addition with benzyl and allyl bromides. Further reduction leads to the coupling products bibenzyl and 1,5-hexadienes Methyl-3-hexene-l,6-dicarb-oxylate can be prepared from butadiene and CO by electroreduction if di-Fe dicyclopentadienyl tetracarbonyl is used as redox catalyst Electro-generated low-valent tungsten species are able to reductively dimerize benzaldehyde to stilbene according to Eq. 83. The reduction potential was controlled at the third wave of the WClg catalyst (V = -1900 mV/SCE)... 

The reaction of an isocyanide containing an acidic hydrogen with copper(I) oxide and an activated olefin or a ketone [Eq. (123)] provides a synthesis of either pyrrolines or oxazolines, respectively (251,252). Addition of allyl bromide gave the coupling product with the allyl carbanion derived from allyl isocyanide. Oxazolines are obtained in yields as high as 957o> not pyrrolines because of competing dimerization... 

Asymmetric Coupling Reactions of Chiral Grignard Reagents Derived from Ephedrine Derivatives. Asymmetric coupling reactions of Allyl Bromide and chiral Grignard reagents derived from ephedrine methyl ether in the presence of Copper(I) Iodide (10 mol %) followed by oxidation affords optically active homoallyl alcohols with 60% ee (eq 12). ... 

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