Tertiary carbon, aliphatic nucleophilic substitution

The essential features of the mechanism for aliphatic nucleophilic substitution at tertiary carbon were established in studies by Hughes and Ingold." ° However, as chemists probed more deeply, the problems associated with the characterization of borderline reaction mechanisms were encountered, and controversy remains to this day about whether these problems have been entirely solved." What is generally accepted is that ferf-butyl derivatives undergo borderline solvolysis reactions through a ferf-butyl carbocation intermediate that is too unstable to diffuse freely through nucleophilic solvents such as methanol and water. The borderline nature of substitution reactions at tertiary carbon is exemplihed by the following observations. 

There is an ongoing controversy about whether there is any stabilization of the transition state for nucleophilic substitution at tertiary aliphatic carbon from interaction with nucleophilic solvent." ° This controversy has developed with the increasing sophistication of experiments to characterize solvent effects on the rate constants for solvolysis reactions. Grunwald and Winstein determined rate constants for solvolysis of tert-butyl chloride in a wide variety of solvents and used these data to define the solvent ionizing parameter T (Eq. 3). They next found that rate constants for solvolysis of primary and secondary aliphatic carbon show a smaller sensitivity (m) to changes in Y than those for the parent solvolysis reaction of tert-butyl chloride (for which m = 1 by definition). A second term was added ( N) to account for the effect of changes in solvent nucleophilicity on obsd that result from transition state stabilization by a nucleophilic interaction between solvent and substrate. It was first assumed that there is no significant stabilization of the transition state for solvolysis of tert-butyl chloride from such a nucleophilic interaction. However, a close examination of extensive rate data revealed, in some cases, a correlation between rate constants for solvolysis of fert-butyl derivatives and solvent nucleophicity. " ... 

The most common preparations of amines on insoluble supports include nucleophilic aliphatic and aromatic substitutions, Michael-type additions, and the reduction of imines, amides, nitro groups, and azides (Figure 10.1). Further methods include the addition of carbon nucleophiles to imines (e.g. the Mannich reaction) and oxidative degradation of carboxylic acids or amides. Linkers for primary, secondary, and tertiary amines are discussed in Sections 3.6, 3.7, and 3.8. 

Reaction with Nitrogen Nucleophiles. The acid-catalyzed reaction of primary, secondary, and tertiary amines with ethyleneimine yields asymmetrically substituted ethylenediamines (71). Steric effects dominate basicity in the relative reactivity of various amines in the ring-opening reaction with ethyleneimine (72). The use of carbon dioxide as catalyst in the aminoethylation of aliphatic amines, for which a patent application has been filed (73), has two advantages. First, the corrosive salts produced when mineral acids are used as catalysts (74,75) are no longer formed, and second, the reaction proceeds with good yields under atmospheric pressure. 

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