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Carbon-metal bonds vinyl halide reactions

Substitution at the Carbon—Chlorine Bond. Vinyl chloride is generally considered inert to nucleophilic replacement compared to other alkyl halides. However, the chlorine atom can be exchanged under nucleophilic conditions in the presence of palladium [7440-05-3] Pd, and certain other metal chlorides and salts. Vinyl alcoholates, esters, and ethers can be readily produced from these reactions. [Pg.414]

The activated nickel powder is easily prepared by stirring a 1 2.3 mixture of NiL and lithium metal under argon with a catalytic amount of naphthalene (1(7 mole % based on nickel halide) at room temperature for 12 h in DME. The resulting black slurry slowly settles after stirring is stopped and the solvent can be removed via cannula if desired. Washing with fresh DME will remove the naphthalene as well as most of the lithium salts. For most of the nickel chemistry described below, these substances did not affect the reactions and hence they were not removed. The activated nickel slurries were found to undergo oxidative addition with a wide variety of aryl, vinyl, and many alkyl carbon halogen bonds. [Pg.231]

The first step in the cycle, analogous to the cross-coupling reactions, is the oxidative addition of an aryl (vinyl) halide or sulfonate onto the low oxidation state metal, usually palladium(O). The second step is the coordination of the olefin followed by its insertion into the palladium-carbon bond (carbopalladation). In most cases palladium is preferentially attached to the sterically less hindered end of the carbon-carbon double bond. The product is released from the palladium in a / -hydrogen elimination and the active form of the catalyst is regenerated by the loss of HX in a reductive elimination step. To facilitate the process an equivalent amount of base is usually added to the reaction mixture. [Pg.21]

The transition metal catalyzed carbon-carbon bond formation between organomagnesium reagents and aryl (vinyl) halides has been one of the pioneering entries into cross-coupling chemistry. The reaction has been widely utilized since than in azine chemistry,22 with the limitation that the functional group tolerance of Grignard reagents is only moderate. Here only some of the more recent developments will be mentioned. [Pg.144]

The reaction sequence in the vinylation of aromatic halides and vinyl halides, i.e. the Heck reaction, is oxidative addition of the alkyl halide to a zerovalent palladium complex, then insertion of an alkene and completed by /3-hydride elimination and HX elimination. Initially though, C-H activation of a C-H alkene bond had also been taken into consideration. Although the Heck reaction reduces the formation of salt by-products by half compared with cross-coupling reactions, salts are still formed in stoichiometric amounts. Further reduction of salt production by a proper choice of aryl precursors has been reported (Chapter III.2.1) [1]. In these examples aromatic carboxylic anhydrides were used instead of halides and the co-produced acid can be recycled and one molecule of carbon monoxide is sacrificed. Catalytic activation of aromatic C-H bonds and subsequent insertion of alkenes leads to new C-C bond formation without production of halide salt byproducts, as shown in Scheme 1. When the hydroarylation reaction is performed with alkynes one obtains arylalkenes, the products of the Heck reaction, which now are synthesized without the co-production of salts. No reoxidation of the metal is required, because palladium(II) is regenerated. [Pg.203]

The Ullmann-type reaction that is homocoupling of aryl or vinyl halides is conveniently mediated by copper at high temperature. The copper powder serves as a zerovalent metal. The classical Ullmann reaction reported in 1901 has long been employed by chemists to generate a carbon-carbon bond between two aromatic nuclei. [Pg.201]

Not only noble metal complexes, but also nickel complexes undergo oxidative addition reactions. Fahey found that a variety of vinyl and aryl halides react with (R3P)2Ni(C2H4) to form a stable carbon-metal o-bond 24). Forex-ample, tetrachloroethylene affords /ran. -chloro(trichlorovinyl)bi s(triphenyl-phosphine)nickel. [Pg.47]

The 1,2-insertion of alkenes into transition metal-carbon o-bond leads to C-C bond formation under mild conditions, as described in Chapter 6. This reaction is considered to be a crucial step in the coordination polymerization and carbometalation of alkenes catalyzed by transition metal complexes. A common and important carbometalation is the Heck-type arylation or vinylation of alkene catalyzed by Pd complexes [118], The arylation of alkene, most typically, involves the formation of arylpalladium species and insertion of alkene into the Pd-aryl bond as shown in Scheme 5.20. The arylpalladium species is formed by the oxidative addition of aryl halides to Pd(0) complexes or the transmetalation of aryl compounds of main group metals with Pd(II) complexes. Insertion of alkene into the Pd-aryl bond produces 2-arylalkylpalladium species whose y6-hydrogen elimination leads to the arylalkene. Oxidative chlorination of the 2-arylalkylpalladium intermediate forms chloroalkanes as the product. [Pg.255]

Monomers with electron-rich double bonds produce one-to-one copolymers with monomers having electron-poor double bonds in reaction systems that also contain certain Lewis acids. These latter are halides or alkyl halides of nontransition metal elements, including AlCb, ZnCh, SnCL, BF3, AI(CH2CH3)Cl2, alkyl boron halides, and other compounds. The acceptor monomer generally has a cyano or carbonyl group conjugated to a vinyl double bond. Examples are acrylic and methacrylic acids and their esters, acrylonitrile, vinyl ketones, maleic anydride, fumaric esters, vinylidene cyanide, sulfur dioxide, and carbon monoxide. The variety of donor molecules is large and includes various olefins, styrene, isoprene, vinyl halides and esters, vinylidene halides, and allyl monomers [30]. [Pg.270]

Due to sluggish reactivity of aryl and vinyl halides in nucleophiUc substitution reactions, the formation of sulfur-carbon(sp ) bonds is typically carried out using transition metal catalysis [22-27]. While the field is dominated by the use of palladium, copper, and nickel catalysts, considerable advances have been made using more abundant metal catalysts such as iron. Additionally, a number of transition metal-fiee approaches have been developed for the formation of sulfur-carbon(sp ) bonds. The following sections will highlight representative examples of C—S bond forming reactions. [Pg.481]


See other pages where Carbon-metal bonds vinyl halide reactions is mentioned: [Pg.1683]    [Pg.5647]    [Pg.5646]    [Pg.122]    [Pg.439]    [Pg.272]    [Pg.82]    [Pg.115]    [Pg.647]    [Pg.452]    [Pg.834]    [Pg.224]    [Pg.313]    [Pg.90]    [Pg.270]    [Pg.530]    [Pg.158]    [Pg.439]    [Pg.188]    [Pg.258]    [Pg.57]    [Pg.133]    [Pg.47]    [Pg.40]    [Pg.186]    [Pg.467]    [Pg.148]    [Pg.520]    [Pg.44]    [Pg.881]    [Pg.174]    [Pg.186]    [Pg.305]    [Pg.520]    [Pg.742]    [Pg.44]    [Pg.295]   
See also in sourсe #XX -- [ Pg.1109 ]




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Bonding carbon-metal bond

Bonds carbon metal

Bonds carbon-metal bond

Bonds vinylic

Carbon halides

Carbon-metal bond formation vinyl halide reactions

Halide bond

Metal halides reactions

Vinyl carbon

Vinyl carbonates

Vinyl halides

Vinyl halides reactions

Vinyl reaction

Vinylic carbon

Vinylic halide reactions

Vinylic halides

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