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Nucleophiles, partitioning of carbocations between addition and deprotonation

Carbocations, partitioning between addition of nucleophiles and deprotonation, 35, 67... [Pg.335]

How Does Structure Determine Organic Reactivity Partitioning of Carbocations between Addition of Nucleophiles and Deprotonation... [Pg.67]

Partitioning of carbocations between addition of nucleophiles and deprotonation, 35, 67 Perchloro-organic chemistry structure, spectroscopy and reaction pathways, 25, 267 Permutational isomerization of pentavalent phosphorus compounds, 9, 25 Phase-transfer catalysis by quaternary ammonium salts, 15, 267 Phosphate esters, mechanism and catalysis of nucleophilic substitution in, 25, 99 Phosphorus compounds, pentavalent, turnstile rearrangement and pseudoration in permutational isomerization, 9, 25... [Pg.339]

It is often difficult to understand at an intuitive level the explanation for the effect of changing substituents on the rate constant ratio kjkp for partitioning of carbocations between nucleophilic addition of solvent and deprotonation. In these cases, insight into the origins of the changes in this rate constant ratio requires a systematic evaluation of substituent effects on the following ... [Pg.81]

Fig. 4 Free energy reaction coordinate profiles that illustrate a change in the relative kinetic barriers for partitioning of carbocations between nucleophilic addition of solvent and deprotonation resulting from a change in the curvature of the potential energy surface for the nucleophile addition reaction. This would correspond to an increase in the intrinsic barrier for the thermoneutral carbocation-nucleophile addition reaction. Fig. 4 Free energy reaction coordinate profiles that illustrate a change in the relative kinetic barriers for partitioning of carbocations between nucleophilic addition of solvent and deprotonation resulting from a change in the curvature of the potential energy surface for the nucleophile addition reaction. This would correspond to an increase in the intrinsic barrier for the thermoneutral carbocation-nucleophile addition reaction.
Table 1 Rate and equilibrium constants for partitioning of substituted a-methyl carbocations R (R2)CCH3+ between nucleophilic addition of solvent (ks) and deprotonation (kp) (Scheme 7)°... [Pg.70]

The partitioning of ferrocenyl-stabilized carbocations [30] between nucleophile addition and deprotonation (Scheme 18) has been studied by Bunton and coworkers. In some cases the rate constants for deprotonation and nucleophile addition are comparable, but in others they favor formation of the nucleophile adduct. However, the alkene product of deprotonation of [30] is always the thermodynamically favored product.120. In other words, the addition of water to [30] gives an alcohol that is thermodynamically less stable than the alkene that forms by deprotonation of [30], but the reaction passes over an activation barrier whose height is equal to, or smaller than, the barrier for deprotonation of [30], These data require that the intrinsic barrier for thermoneutral addition of water to [30] (As) be smaller than the intrinsic barrier for deprotonation of [30] (Ap). It is not known whether the magnitude of (Ap — As) for the reactions of [30] is similar to the values of (Ap - As) = 4-6 kcal mol 1 reported here for the partitioning of a-methyl benzyl carbocations. [Pg.109]

By contrast, [31]-(brosylate) was proposed to show a large amount of reaction through a secondary carbocation intermediate,122 which partitions between nucleophile addition and deprotonation. We are uncertain of how to relate the partitioning of the putative carbocation intermediate of the reaction of [31]-(brosylate) to the partitioning of other carbocations discussed in this review. [Pg.110]

The partitioning of simple tertiary carbocations, ring-substituted 1-phenylethyl carbocations, and cumyl carbocations between deprotonation and nucleophilic addition of solvent strongly favors formation of the solvent adduct. The more favorable partitioning of these carbocations to form the solvent adduct is due, in part, to the greater thermodynamic stability of the solvent... [Pg.110]

Nuclear motion, the principle of least, and the theory of stereoelectronic control, 24, 113 Nucleophiles, partitioning of carbocations between addition and deprotonation. 35, 67 Nucleophilic aromatic photosubstitution, 11,225 Nucleophilic catalysis of ester hydrolysis and related reactions, 5,237 Nucleophilic displacement reactions, gas-phase, 21, 197... [Pg.339]

The effects of a-Mc2NC(0) and a-Mc2NC(S) on the rate constants for partitioning of a-substitutcd l-(4-methoxyphenyl)ethyl carbocations between nucleophilic addition of 50 50 (v/v) MeOH-H20 (ks, s ) and deprotonation by this solvent (ke, s 1) have been examined.128 These substituents lead to 80-fold and > 30 000-fold decreases, respectively, in ks, but to much smaller changes in ke. Ab initio calculations suggest that the partitioning is strongly controlled by the relative thermodynamic stabilities of the neutral products of the reactions. [Pg.319]


See other pages where Nucleophiles, partitioning of carbocations between addition and deprotonation is mentioned: [Pg.354]    [Pg.278]    [Pg.402]    [Pg.242]    [Pg.310]    [Pg.384]    [Pg.318]    [Pg.354]    [Pg.278]    [Pg.402]    [Pg.242]    [Pg.310]    [Pg.384]    [Pg.318]    [Pg.69]    [Pg.71]    [Pg.99]    [Pg.103]    [Pg.319]   
See also in sourсe #XX -- [ Pg.35 , Pg.67 ]

See also in sourсe #XX -- [ Pg.35 , Pg.67 ]

See also in sourсe #XX -- [ Pg.35 , Pg.67 ]

See also in sourсe #XX -- [ Pg.35 , Pg.67 ]




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Additions of nucleophiles

And carbocations

And nucleophilic addition

Carbocation addition

Carbocation-nucleophile addition

Carbocations addition

Carbocations deprotonation

Carbocations nucleophile

Nucleophilic, and carbocations

Of carbocations

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