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Acetylene hydrogen bonding

Stracture is effectively planar with the acetylene hydrogen bonded to the oxygen of the water. [Pg.759]

Acetylene is linear with a carbon-carbon bond distance of 120 pm and carbon-hydrogen bond distances of 106 pm... [Pg.365]

Acetylenic hydrogens are unusual in that they are more shielded than we would expect for protons bonded to sp hybridized carbon This is because the rr electrons circulate around the triple bond not along it (Figure 13 9a) Therefore the induced magnetic field is parallel to the long axis of the triple bond and shields the acetylenic proton (Figure 13 9b) Acetylenic protons typically have chemical shifts near 8 2 5... [Pg.529]

Rea.ctlons, Propargyl alcohol has three reactive sites—a primary hydroxyl group, a triple bond, and an acetylenic hydrogen—making it an extremely versatile chemical intermediate. [Pg.103]

Methylbutynol. 2-Methyl-3-butyn-2-ol [115-19-5] prepared by ethynylation of acetone, is the simplest of the tertiary ethynols, and serves as a prototype to illustrate their versatile reactions. There are three reactive sites, ie, hydroxyl group, triple bond, and acetylenic hydrogen. Although the triple bonds and acetylenic hydrogens behave similarly in methylbutynol and in propargyl alcohol, the reactivity of the hydroxyl groups is very different. [Pg.112]

Since both complete hydrogenation of acetylene or any hydrogenation of the ethylene results in the production of a less valuable product such as ethane, conditions must be chosen carefiiUy and a catalyst must be used that is both sufficiently active for acetylene hydrogenation and extremely selective to avoid ethylene hydrogenation. Since hydrogenation of acetylenic bonds proceeds stepwise and since acetylene is more strongly adsorbed on the catalytic... [Pg.199]

The four mechanisms discussed above, of the action of inhibitors remain essentially unchanged. Further work on acetylenic alcohols has indicated that barrier films can form owing to crosslinking by hydrogen bonding and synergistic interactions . Theoretical treatments of the electrochemical... [Pg.824]

A similar quantitative treatment of sulphoxides as hydrogen bonding acceptors has been obtained by comparing the IR frequency shift AvOH of the C—I bond in an acetylenic iodide such as IC=CI (Avc j) due to formation of a C—T complex with phenol in various bases. This investigation suggests that sulphoxides belong to the same family as carbonyls, phosphine oxides, arsine oxides and their derivatives90. [Pg.560]

Hydrogenations involving consecutive reactions are common in the organic process industry and even in the hydrogenation of fats. In the fine chemicals industry we have examples of acetylenic (triple) bonds to be selectively converted to olefinic (double) bonds. Lange et al. (1998) have shown, for the comversion of the model substance 2-hexyne into cis-2-hexene, how catalytically active microporous thin-film membranes can accomplish 100% selectivity. This unusual selectivity is attributed to avoidance of backmixing. [Pg.171]

The dangerous reactions of halogenation, which affect either the acetylenic hydrogen atom or the triple bond have just been described. There are also reactions which lead to accidents and affect one of the acetylenic sites. [Pg.245]

Again, we need to define a coupling constant J to set up this experiment. Here for optimum sensitivity we have used an average value for direct (one-bond) carbon-hydrogen coupling constants of 160 Hz. This choice works well for most CH bonds, but is rather low if an acetylenic CH bond is present. [Pg.44]

This observation may well explain the considerable difference between metal-olefin and metal-acetylene chemistry observed for the trinuclear metal carbonyl compounds of this group. As with iron, ruthenium and osmium have an extensive and rich chemistry, with acetylenic complexes involving in many instances polymerization reactions, and, as noted above for both ruthenium and osmium trinuclear carbonyl derivatives, olefin addition normally occurs with interaction at one olefin center. The main metal-ligand framework is often the same for both acetylene and olefin adducts, and differs in that, for the olefin complexes, two metal-hydrogen bonds are formed by transfer of hydrogen from the olefin. The steric requirements of these two edgebridging hydrogen atoms appear to be considerable and may reduce the tendency for the addition of the second olefin molecule to the metal cluster unit and hence restrict the equivalent chemistry to that observed for the acetylene derivatives. [Pg.290]

There are not many drugs that are alkynes however, one good example is ethinyl estradiol (Fig. 4.6). Even though ethinyl estradiol is not an aryl alkyne, the acetylenic group is attached to a tertiary carbon and not adjacent to an a-carbon-hydrogen bond. [Pg.90]

See other pages where Acetylene hydrogen bonding is mentioned: [Pg.66]    [Pg.66]    [Pg.373]    [Pg.66]    [Pg.57]    [Pg.654]    [Pg.69]    [Pg.159]    [Pg.196]    [Pg.279]    [Pg.280]    [Pg.300]    [Pg.106]    [Pg.1217]    [Pg.39]    [Pg.365]    [Pg.453]    [Pg.66]    [Pg.233]    [Pg.411]    [Pg.45]    [Pg.71]    [Pg.41]    [Pg.291]    [Pg.253]    [Pg.423]    [Pg.139]    [Pg.165]    [Pg.67]    [Pg.200]    [Pg.238]    [Pg.121]    [Pg.247]    [Pg.120]    [Pg.241]    [Pg.496]   
See also in sourсe #XX -- [ Pg.89 ]



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Insertion, into metal-hydrogen bonds acetylenes

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