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Carbon multiple

The most general methods for the syntheses of 1,2-difunctional molecules are based on the oxidation of carbon-carbon multiple bonds (p. 117) and the opening of oxiranes by hetero atoms (p. 123fl.). There exist, however, also a few useful reactions in which an a - and a d -synthon or two r -synthons are combined. The classical polar reaction is the addition of cyanide anion to carbonyl groups, which leads to a-hydroxynitriles (cyanohydrins). It is used, for example, in Strecker s synthesis of amino acids and in the homologization of monosaccharides. The ff-hydroxy group of a nitrile can be easily substituted by various nucleophiles, the nitrile can be solvolyzed or reduced. Therefore a large variety of terminal difunctional molecules with one additional carbon atom can be made. Equally versatile are a-methylsulfinyl ketones (H.G. Hauthal, 1971 T. Durst, 1979 O. DeLucchi, 1991), which are available from acid chlorides or esters and the dimsyl anion. Carbanions of these compounds can also be used for the synthesis of 1,4-dicarbonyl compounds (p. 65f.). [Pg.50]

Hydrogenation of Carbon-Carbon Multiple Bonds and Cyclopropane Rings... [Pg.100]

Oxidation of Carbon Atoms in Carbon-Carbon Multiple Bonds... [Pg.123]

Electrochemical Fluorination. In the Simons electrochemical fluorination (ECF) process the organic reactant is dissolved in anhydrous hydrogen fluoride and fluorinated at the anode, usually nickel, of an electrochemical ceU. This process has been reviewed (6). Essentially all hydrogen atoms are substituted by fluorine atoms carbon—carbon multiple bonds are saturated. The product phase is heavier than the HF phase and insoluble in it and is recovered by phase separation. [Pg.298]

Oxidation. The oxidation reactions of organoboranes have been reviewed (5,7,215). Hydroboration—oxidation is an anti-Markovnikov cis-hydration of carbon—carbon multiple bonds. The standard oxidation procedure employs 30% hydrogen peroxide and 3 M sodium hydroxide. The reaction proceeds with retention of configuration (216). [Pg.314]

The bonding between carbon monoxide and transition-metal atoms is particularly important because transition metals, whether deposited on soHd supports or present as discrete complexes, are required as catalysts for the reaction between carbon monoxide and most organic molecules. A metal—carbon ( -bond forms by overlapping of metal orbitals with orbitals on carbon. Multiple-bond character between the metal and carbon occurs through formation of a metal-to-CO TT-bond by overlap of metal-i -TT orbitals with empty antibonding orbitals of carbon monoxide (Fig. 1). [Pg.50]

Fluorine Stabilized Sulfur-Carbon Multiple Bonds Seppelt, K Angeu Chem 103. 399-J13 232... [Pg.22]

Tnfluoromethyldiazomethane behaves as atypical diazoalkane in its additions to carbon-carbon multiple bonds [9] For example, its reactions with ethylene and... [Pg.807]

Alkenes, alkynes, and arenes (aromatic compounds) all contain carbon-carbon multiple bonds. Alkenes have a double bond, alkynes have a triple bond, and cneues have alternating double and single bonds in a six-membered ring of carbon atoms. Because of their structural similarities, these compounds also have chemical similarities. [Pg.74]

Terpenoids are classified according to the number of five-carbon multiples they contain. Monoterpenoids contain 10 carbons and are derived from two isopentenyl diphosphates, sesquiterpenoids contain 15 carbons and are derived from three isopentenyl diphosphates, diterpenoids contain 20 carbons and are derived from four isopentenyl diphosphates, and so on, up to triterpenoids (C30) and tetraterpenoids (C40). Monoterpenoids and sesquiterpenoids are found primarily in plants, bacteria, and fungi, but the higher terpenoids occur in both plants and animals. The triterpenoid lanosterol, for example, is the precursor from which steroid hormones are made, and the tetraterpenoid /3-carotene is a dietary source of vitamin A (Figure 27.6). [Pg.1071]

Org. Chem. 1978, 43, 4207-4215 a related azepine formation through addition of N-unsubstituted azidirines to electrophilic carbon-carbon multiple bond systems such as acrylonitrile followed by aza-[3,3]-Claisen rearrangement was reported by Hassner (c) A. Hassner, R. D Costa,... [Pg.71]

The aim of this volume is to convince the reader that metal carbene complexes have made their way from organometallic curiosities to valuable - and in part unique - reagents for application in synthesis and catalysis. But it is for sure that this development over 4 decades is not the end of the story there is both a need and considerable potential for functional organometallics such as metal carbon multiple bond species which further offer exciting perspectives in selective synthesis and catalysis as well as in reactions applied to natural products and complex molecules required for chemical architectures and material science. [Pg.369]

At this stage it is helpful to know that compounds of hydrogen and carbon are called hydrocarbons. They include methane, CH4 (1) ethane, C2H6 (2) and benzene, C6H6 (3). Hydrocarbons that have no carbon-carbon multiple bonds are called alkanes. Thus, methane and ethane are both alkanes. The unbranched alkanes with... [Pg.59]

Functional groups are either attached to the carbon backbone of a molecule or form part of that chain. Examples are the chlorine atom in chloroethane, CH3CH2CI, and the OFF group in ethanol, CFF CI OFi. Carbon-carbon multiple bonds, such as the double bond in 2-butene, are also often considered functional groups. Table 19.1 lists the most common functional groups. Double and triple carbon-carbon bonds were considered in Chapter 18. In the following eight... [Pg.873]

Eisch, John J., Boron-Carbon Multiple Bonds. 39 355... [Pg.466]

In Part 2 of this book, we shall be directly concerned with organic reactions and their mechanisms. The reactions have been classified into 10 chapters, based primarily on reaction type substitutions, additions to multiple bonds, eliminations, rearrangements, and oxidation-reduction reactions. Five chapters are devoted to substitutions these are classified on the basis of mechanism as well as substrate. Chapters 10 and 13 include nucleophilic substitutions at aliphatic and aromatic substrates, respectively, Chapters 12 and 11 deal with electrophilic substitutions at aliphatic and aromatic substrates, respectively. All free-radical substitutions are discussed in Chapter 14. Additions to multiple bonds are classified not according to mechanism, but according to the type of multiple bond. Additions to carbon-carbon multiple bonds are dealt with in Chapter 15 additions to other multiple bonds in Chapter 16. One chapter is devoted to each of the three remaining reaction types Chapter 17, eliminations Chapter 18, rearrangements Chapter 19, oxidation-reduction reactions. This last chapter covers only those oxidation-reduction reactions that could not be conveniently treated in any of the other categories (except for oxidative eliminations). [Pg.381]

ADDITION TO CARBON-CARBON MULTIPLE BONDS unstabilized by resonance ... [Pg.980]

See other pages where Carbon multiple is mentioned: [Pg.40]    [Pg.305]    [Pg.7]    [Pg.103]    [Pg.444]    [Pg.940]    [Pg.947]    [Pg.965]    [Pg.970]    [Pg.1029]    [Pg.972]    [Pg.974]    [Pg.976]    [Pg.978]    [Pg.982]    [Pg.984]    [Pg.986]    [Pg.988]    [Pg.990]    [Pg.992]    [Pg.994]    [Pg.996]    [Pg.998]    [Pg.1000]    [Pg.1002]    [Pg.1004]    [Pg.1006]    [Pg.1008]    [Pg.1010]    [Pg.1012]    [Pg.1014]   
See also in sourсe #XX -- [ Pg.29 , Pg.30 ]



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Addition to carbon-hetero multiple

Addition to carbon-hetero multiple bonds

Addition to carbon-heteroatom multiple bonds

Addition to the carbon-nitrogen multiple bonds

Alkenes multiple carbon-heteroatom bond

Beta-eliminations giving multiple bonds between carbon and other ELEMENTS

Boron-Carbon Multiple Bonding in Open-Chain Unsaturated Organoboranes

Boron-carbon multiple bonds

Carbon Multiple Bonds

Carbon dioxide law of multiple proportions

Carbon monoxide law of multiple proportions

Carbon multiple bonds, addition

Carbon multiple resonance

Carbon multiplicities

Carbon multiplicities

Carbon-Nitrogen Multiple Bond Radical Acceptors

Carbon-heteroatom multiple

Carbon-heteroatom multiple bonds

Carbon-heteroatom multiple bonds, nucleophilic

Carbon-heteroatom multiple bonds, nucleophilic addition

Carbon-nitrogen multiple bonds

Carbon-proton coupling constants multiple-bond couplings

Catalysis, multiple metal-carbon

Catalysis, multiple metal-carbon bonds

D Proton-Carbon (Multiple Bond) Correlated Spectroscopy

Fragmentations yielding multiple bonds between carbon and a heteroatom

Hydrocarbon metal-carbon multiple bond

John J., Boron Carbon Multiple Bonds

Ligands forming metal-carbon multiple bonds

Metal-Carbon Multiple Bonding

Metal-carbon multiple bond linkages

Multiple bonding boron-carbon

Multiple metal carbon bonds, complexes

Multiple metal-carbon bonds

Multiple pulse techniques, carbon

Multiple-wall carbon nanotube

Multiple-wall carbon nanotube method

Multiple-walled carbon nanotube

Nucleophiles addition to carbon-heteroatom multiple bonds

Nucleophilic Addition to Carbon-Heteroatom Multiple Bonds

Organometallic compounds with metal-carbon multiple bonds

Other Carbon-Heteroatom Multiple Bonds

Phosphorus Carbon Multiple Bonds

Polymerization of isocyanide by multiple insertion into metal-carbon bond

Uranium-carbon multiple bond

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