Preassociation reactions, nucleophilic substitution

The yield of the nucleophilic substitution product from the stepwise preassociation mechanism k[ = k. Scheme 2.4) is small, because of the low concentration of the preassociation complex (Xas 0.7 M for the reaction of X-2-Y). Formally, the stepwise preassociation reaction is kinetically bimolecular, because both the nucleophile and the substrate are present in the rate-determining step ( j). In fact, these reactions are borderline between S l and Sn2 because the kinetic order with respect to the nucleophile cannot be rigorously determined. A small rate increase may be due to either formation of nucleophile adduct by bimolecular nucleophilic substitution or a positive specific salt effect, whUe a formally bhnole-cular reaction may appear unimolecular due to an offsetting negative specific salt effect on the reaction rate. 

The change from a stepwise preassociation mechanism through a triple ion intermediate to an uncoupled concerted reaction occurs as the triple ion becomes too unstable to exist in an energy well for the time of a bond vibration ( 10 s). The borderline between these two reaction mechanisms is poorly marked, and there are no clear experimental protocols for its detection. These two reaction mechanisms cannot be distinguished by experiments designed to characterize their transition states, which lie at essentially the same position in the inner upper right hand corner of Figure 2.3. Only low yields of the nucleophilic substitution product are obtained from both stepwise preassociation and uncoupled concerted reactions, because for formation of the preassociation complex in water is small... 

An important question is whether nucleophilic substitution at tertiary carbon proceeds though a carbocation intermediate that shows a significant chemical barrier to the addition of solvent and other nucleophiles. The yield of the azide ion substitution product from the reaction of 5-Cl is similar to that observed for the reactions of X-2-Y when this product forms exclusively by conversion of the preassociation complex to product. Therefore the carbocation 5 is too unstable to escape from an aqueous solvation shell and undergo diffusion-controlled trapping by azide ion. This result sets a lower limit of w fcj > -d 1.6 x 10 ° s (Scheme 2.4) " for addition of solvent to the ion pair intermediate 5" C1 . 

The nucleophilic substitution reactions of anilines with ero-2-norbomyl arenesulfonates, 2, present an interesting example of the preassociation mechanism55 (Scheme 1). The rate is faster with 2-exo (k2 = 15.9 x 10 4 and 3.24 x 10-5 M 1 s 1 when X = Z = H in MeOH and MeCN at 60.0 °C, respectively) than with 2-endo (k2 = 0.552 x 10 5 M 1 s 1 with X = Z = H in MeOH at 60.0 °C). These reactions are characterized by a large pz (1.8 and 1.2 for 2-exo and 2-endo) coupled with a small magnitude of px (—0.21 and —0.15 for 2-exo and 2-endo). The pz values for the aniline reactions are even larger than those for the SY 1 solvolysis in MeOH (pz =1.5 and 1.0 for solvolysis of 2-exo and 2-endo). Thus the abnormal substituent effect in the anilinolysis of 2 can only be accounted for by the preassociation mechanism of Scheme 1. The upper route is the normal S/v 1 pathway, and the lower route is the preassociation pathway. The preassociation step, Xass, and association of the Nu to the ion pairs, kn. occur in a diffusion limited or fast process and k is the rate-limiting step. This mechanism leads to second-order kinetics and therefore is an SY/2 process, but structural effects on rates are very similar to those of S l reactions, since the R+ Z pair consists essentially of the two free ions. 

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