Alkynes chloride dimer

Cheng and Muralirajan devised a rhodium(III)-catalyzed, chelate-assisted C-H activation/annulation reaction as a means to prepare numerous substituted cinnolinium salts by treating azobenzenes with alkynes in the presence of pentamethylcyclopentadienylrhodium(III) chloride dimer [(RhCp Cl2)2] and copper(II) tetrafluoroborate hexahydrate (Cu(BF4)2 6H20) in tert-butanol in air at 70°C (Scheme 2) (13CEJ6198). The salts were obtained in good-to-high yields and were subsequently... 

DNA sequencing and. 1113 Electrospray ionization (ESI) mass spectrometry, 417-418 Electrostatic potential map, 37 acetaldehyde, 688 acetamide, 791,922 acetate ion. 43. 53, 56, 757 acetic acid. 53. 55 acetic acid dimer, 755 acetic anhydride, 791 acetone, 55, 56. 78 acetone anion, 56 acetyl azide, 830 acetyl chloride, 791 acetylene. 262 acetylide anion, 271 acid anhydride, 791 acid chloride, 791 acyl cation, 558 adenine, 1104 alanine, 1017 alanine zwitterion, 1017 alcohol. 75 alkene, 74, 147 alkyl halide, 75 alkyne. 74... 

With the bulky metallo-organic Pd(II) catalyst 98, on the other hand, selective formation of 99 was possible here functional groups are tolerated that would react with an Ag(I) catalyst (for example, terminal alkynes, alkyl chlorides, alkyl bromides and alkyl iodides) [59]. With l,n-diallenyl diketones (100), easily accessible by a bidirectional synthesis, up to 52-membered macrocycles (101) could be prepared in an end-group differentiating intramolecular reaction (Scheme 15.26) [60], For ring sizes lager than 12 only the E-diastereomer is formed overall yields of the macrocydes varied between 17 and 38%. Only with tethers shorter than 11 carbon atoms could the Z-diastereomer of the products be observed, a stereoisomer unknown from the intermolecular dimerization reactions of 96. 

Another reaction of 1-alkynes that extends the carbon chain is a coupling reaction in which the alkyne dimerizes under the influence of a cuprous salt, usually cuprous ammonium chloride ... 

The cyclopropanation of alkenes, alkynes, and aromatic compounds by carbenoids generated in the metal-catalyzed decomposition of diazo ketones has found widespread use as a method for carbon-carbon bond construction for many years, and intramolecular applications of these reactions have provided a useful cyclization strategy. Historically, copper metal, cuprous chloride, cupric sulfate, and other copper salts were used most commonly as catalysts for such reactions however, the superior catalytic activity of rhodium(ll) acetate dimer has recently become well-established.3 This commercially available rhodium salt exhibits high catalytic activity for the decomposition of diazo ketones even at very low catalyst substrate ratios (< 1%) and is less capricious than the old copper catalysts. We recommend the use of rhodium(ll) acetate dimer in preference to copper catalysts in all diazo ketone decomposition reactions. The present synthesis describes a typical cyclization procedure. 

For thermally induced [2 + 2] cycloadditions, the concerted mechanism is operative only in particular cases, such as in the reactions between an alkene or alkyne and a ketene. The ketene can be generated directly in the reaction mixture from the appropriate acid chloride with triethylamine. The cycloaddition reaction is stereospecific and occurs exclusively in a cis fashion. Although the intermolecular cycloaddition with ketene itself proceeds in poor yields due to the propensity of the unsubstituted ketene to undergo dimerization, it is quite an efficient reaction with ketenes containing electron-withdrawing substituents. Usually, a-chloro ketenes are employed as reagents formed in situ from the corresponding a-chloro acid chlorides. Typical examples are represented in the preparation of cycloadducts such as 378 and 379 (Scheme 2.127). The latter cycloadduct, prepared in modest yield (ca. 20%),... 

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. 

Dien-4-ynes 136 (R -R = alkyl) are produced from propargylic carbonates 135 and terminal alkynes in the presence of a palladium-phosphine complex and copper(I) iodide. The linear co-dimerization of terminal acetylenes and 1,3-dienes is catalyzed by ruthenium(cyclooctadiene)(cyclooctatriene)(trialkylphosphine) (alkyl = Et, Bu or octyl) thus 1-hexyne and methyl penta-2,4-dienoate give a mixture of the eneynes 137 and 138. Coupling of octa-l,7-diyne (139) with the acetylenic bromo acid 140 in aqueous THF-methanol containing butylamine, hydroxylamine hydrochloride and copper(I) chloride gave a mixture of the triynyl acids 141 and 142. ... 

Recent studies on the allylation of alkynes with bis (7r-allyl) nickel have revealed that the Ni(0) generated in this process causes the trimeri-zation and, more importantly, the reductive dimerization of a portion of the alkyne (8). A deuterolytic work-up led to the terminally di-deuter-ated diene (5), supporting the presence of a nickelole precursor (4) (Scheme 1). The further interaction of 4 with 1, either in a Diels-Alder fashion (6) or by alkyne insertion in a C-Ni bond (7), could lead to the cyclic trimer 8 after extrusion of Ni(0), thereby accounting for the trimerizing action of Ni(0) on alkynes. This detection of dimer 5 then provided impetus for the synthesis of the unknown nickelole system to learn if its properties would accord with this proposed reaction scheme. Therefore, E,E-l,4-dilithio-l,2,3,4-tetraphenyl-l,3-butadiene (9) was treated with bis (triphenylphosphine) nickel (II) chloride or l,2-bis(di-phenylphosphino ethane)nickel(II) chloride to form the nickelole 10 (9) (Scheme 2). The nickelole reacted with dimethyl acetylenedicarboxylate to yield 11 and with CO to produce 12. Finally, in keeping with the hypothesis offered in Scheme 1, 10a did act as a trimerizing catalyst toward diphenylacetylene (13) to yield 14. 

Hydrocyanation of acetylene is catalyzed by an aqueous solution of copper(I) chloride and ammonium chloride however, byproducts are also formed, viz., acetaldehyde and vinylacetylene, the latter arising by dimerization of acetylenes. Hydrocyanation, followed by reduction of alkynes leading to secondary nitriles, is catalyzed by Co(CN)5 in the atmosphere of H2 or by Ni(CN)4 in the presence of BH4 cyanide. 

Further attempts to increase the kinetics and biocompatibility of 1,3-dipolar cycloadditions led organic chemists to explore altemative dipoles that react with multiple-bond reaction partners. Nitrile oxides are highly reactive dipoles that can react with various alkenes and alkynes to provide isoxazolines and isoxazoles, respectively. In the absence of a suitable reacting partner, nitrile oxides tend to dimerize to form fiiroxane derivatives, or can alternatively act as electrophiles. However, when generated in situ from suitable precursors such as hydroximoyl chlorides or by mild oxidation directly from oximes, nitrile oxides were successfully applied to the labeling of nucleic acids [43], peptides [44] and carbohydrates [45] (Fig. 7). 

Alkyne molecules are often linked together in their reactions with transition metal compounds. An early example of this, discovered by Niewland in 1931, was the linear dimerization of ethyne to but-l-en-3-yne, catalysed by copper(I) chloride. The product was for many years an intermediate in the manufacture of chloroprene for synthetic rubber. 

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