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Propargyl compounds carbonylation

Allylations, allenylations, and propargylations of carbonyl compounds in aqueous media can also be carried out with preformed organic tin reagent, rather than the use of metals.86,87,88 For example, the allylation reaction of a wide variety of carbonyl compounds with tetraal-lyltin was successfully carried out in aqueous media by using scandium trifluoromethanesulfonate (scandium triflate) as a catalyst (Eq. 8.40).89 A phase-transfer catalyst (PTC) was found to help the allylation mediated by tin at room temperature without any other assistance.90... [Pg.231]

Acceptor-substituted allenes can be prepared from the corresponding propargyl precursors by prototropic isomerization (see Section 7.2.2). Conversely, such allenes can also be used to synthesize propargyl compounds. For example, treatment of the sulfoxides 417 with 1 equivalent of a lithiation reagent leads to the intermediates 418, which furnish propargyl sulfoxides 419 by hydrolysis (Scheme 7.55) [101]. If the electrophiles used are not protons but primary alkyl halides or carbonyl compounds, the products 420 or 421, respectively, are formed by C,C linkage. [Pg.414]

Allenic esters can be generated by palladium-catalyzed carbonylation of propargyl compounds (see Section 7.2.6). Under the reaction conditions applied, however, succeeding reactions occur directly in many cases, for instance by introduction of a second ester function. Many examples of such carbonylation reactions of allenic esters were summarized in a review by Tsuji and Mandai [136],... [Pg.416]

Propargylic compounds undergo facile Pd-catalysed mono- and di-carbonylations depending on the reaction conditions [6]. The facile monocarbonylation of propargylic... [Pg.203]

The chemistry of asymmetric allylation of carbonyl compounds has further progressed since the review in Comprehensive Asymmetric Catalysis [1] and plenty of papers including reviews [2,3] on chiral catalysts for the reaction have since appeared. This chapter describes new examples of catalytic enantioselec-tive allylation of carbonyl compounds with allylmetals in the presence of a catalytic amount of chiral Lewis acid or chiral Lewis base (Scheme 1). Compounds 1-36 [4-49] shown in Fig. 1 are the chiral catalysts reported since 1998, which have been used in the asymmetric allylation or propargylation of carbonyl compounds. Chiral compounds 37-40 [50-53], which have been utilized in the stoichiometric version, are also candidates for the chiral catalyst (Fig. 2). [Pg.113]

From InCl3, highly reactive low-valent indium(i) species are electrochemically generated and regenerated. These are used for allylation and propargylation of carbonyl compounds (Scheme 3). Of special interest are bisallylations of aromatic and aliphatic esters, since such conversions cannot be achieved by using conventional stoichiometric allylations of esters by means of indium metal or Ini.66... [Pg.652]

Propargylic compounds undergo facile palladium-catalyzed mono- and dicarbonylations, depending on the reaction conditions [9]. The carbonylation of propargylic alcohols has... [Pg.511]

Allylation and propargylation of carbonyl compounds have been surveyed [5]. This section focuses on regio- and stereochemical aspects of the carbonyl allylation reactions in organic and aqueous media. Allylation of carbonyl compounds also proceeds under solvent-free conditions [10] or in liquid carbon dioxide [11]. Allylation with a catalytic amount of indium (0.01-0.1 equiv.) in combination with manganese and chlorotrimethylsilane has been reported [12]. Allylindium reagents have successfully been applied to syntheses of several natural products [13]. [Pg.325]

I-Alkyn-4-ols. Propargylation of carbonyl compounds is achieved in a reaction catalyzed by BFj OEta. The reagent is prepared from PhsPbMgBr and propargyl bromide. [Pg.10]

For a-aUylation and a-propargylation of carbonyl compounds, however, the Tsuji-Trost reaction and related reactions discussed extensively in Part V (Sect. V.2.1) provide a wide range of very satisfactory procedures. Although the Tsuji-Trost reaction has mostly been carried out by using extrastabilized enolates, such as acetoacetates and malonates, subsequent decarboxylation provides more usual a-substituted ketones (Scheme 3). [Pg.695]

Soon afterwards, the same group developed methodologies for the oxidative carbonylation of 4-yn-l-ones and propargylic esters (Scheme 8.22). While 2-cyclopentenone carboxylates were obtained from appropriate carbonyl-substituted alkynes [96], cyclic orthoesters and furanones were successfully synthesized starting from corresponding propargylic compounds [97]. More recently, they also realized the asymmetric version of this reaction [98], which has also been applied in the total synthesis of (—)-AL-2 by Mukai and Miyakoshi [99]. [Pg.157]

Palladium-catalyzed carbonylation of allylic and propargylic compounds offers a potential tool of one-carbon homologation. Particularly, pd-catalyzed carbonylation of propargylic compounds further provides synthetically valuable transformations because of the high reactivity of the intermediary allenyl esters. [Pg.862]

J. Tsuji and J. Kiji, in Transition Metals for Organic Synthesis, Vol. 1, M. Beller and C. Bolm, Eds., Wiley-VCH, Weinheim, 1998, 68-78. Palladium-Catalyzed Carbonylation of Allylic and Propargylic Compounds. [Pg.1492]

Although superficially similar, propargyl compounds do not form t -complex intermediates, but give t -allenic complexes. As part of a catalytic cycle, these can undergo typical reactions, such as coupling (Schemes 9.82 and 9.83), ° ° reduction by formate, alkene insertion and carbonylation (Scheme 9.84). [Pg.357]

The allenyl moiety (2,3-aikadienyl system) in the carbonylation products is a reactive system and further reactions such as intramolecular Diels-Alder and ene reactions are possible by introducing another double bond at suitable positions of the starting 2-alkynyl carbonates. For example, the propargylic carbonate 33 which has l,8(or 1.9)-diene-3-yne system undergoes tandem carbonylation and intramolecular Diels-Alder reaction to afford the polycyclic compound 34 under mild conditions (60 C, 1 atm). The use of dppp as ligand is important. One of the double bonds of the allenyl ester behaves as part of the dieneflSj. [Pg.458]

Acetylene is condensed with carbonyl compounds to give a wide variety of products, some of which are the substrates for the preparation of families of derivatives. The most commercially significant reaction is the condensation of acetylene with formaldehyde. The reaction does not proceed well with base catalysis which works well with other carbonyl compounds and it was discovered by Reppe (33) that acetylene under pressure (304 kPa (3 atm), or above) reacts smoothly with formaldehyde at 100°C in the presence of a copper acetyUde complex catalyst. The reaction can be controlled to give either propargyl alcohol or butynediol (see Acetylene-DERIVED chemicals). 2-Butyne-l,4-diol, its hydroxyethyl ethers, and propargyl alcohol are used as corrosion inhibitors. 2,3-Dibromo-2-butene-l,4-diol is used as a flame retardant in polyurethane and other polymer systems (see Bromine compounds Elame retardants). [Pg.393]


See other pages where Propargyl compounds carbonylation is mentioned: [Pg.257]    [Pg.371]    [Pg.371]    [Pg.649]    [Pg.651]    [Pg.651]    [Pg.509]    [Pg.325]    [Pg.455]    [Pg.238]    [Pg.548]    [Pg.553]    [Pg.297]    [Pg.851]    [Pg.116]    [Pg.534]    [Pg.247]   


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Allylation and Propargylation of Carbonyl Compounds

Carbonylation propargylic compounds

Carbonylation propargylic compounds

Propargyl alcohols carbonyl compounds

Propargyl compounds

Propargylation carbonyls, with indium compounds

Propargylic acetates reactions with carbonyl compounds

Propargylic compounds

Propargylic compounds carbonyl

Propargylic compounds carbonyl

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