Summary Nucleophilic Substitutions

These sections show how a variety of experimental observations led to the proposal of the SN1 and the SN2 mechanisms for nucleophilic substitution. Summary Table 8.9 integrates the material in these sections. 

A large number of nucleophilic substitution reactions involving interconversions of pyridopyrimidines have been reported, the majority of which involve substituents in the pyrimidine ring. This subject has been reviewed previously in an earlier volume in this series which dealt with the theoretical aspects of nucleophilic re-activiti in azines, and so only a summary of the nucelophilic displacements of the substituent groups will be given here. In general, nucleophilic substitutions occur most readily at the 4-position of pyrido-... 

Mechanism 6-1 Allylic Bromination 228 Summary Methods for Preparing Alkyl Halides 229 6-7 Reactions of Alkyl Halides Substitution and Elimination 231 6-8 Second-Order Nucleophilic Substitution The Sn2 Reaction 232 Key Mechanism 6-2 The S j2 Reaction 233 6-9 Generality of the SN2 Reaction 234... 

Summary The rich variety of the coordination chemistry of silicon is discussed and some theoretical issues are raised. In an attempt to understand further the underlying chemistry, some thermodynamic and kinetic parameters for the formation and substitution of pentacoordinate silicon compounds have been measured by NMR methods. Values of -31 3 kJ mol for SHand -100 10 J K mor for A5-were measured for the intramolecular coordination of a pyridine ligand to a chlorosilane moiety. A detailed kinetic analysis of a nucleophilic substitution at pentacoordinate silicon in a chelated complex revealed that substitution both with inversion and retention of configuration at silicon are taking place on the NMR time-scale. The substitution with inversion of configuration is zero order in nucleophile but a retentive route is zero order in nucleophile at low temperature but shows an increasing dependence on nucleophile at higher temperatures. These results are analysed and mechanistic hypotheses are proposed. Some tentative conclusions are drawn about the nature of reactivity in pentacoordinate silicon compounds. 

Summary Nucleophilic substitution and p elimination reactions of alcohols... 

Summary of the Nucleophilic Substitution Reactions of Carboxylic Acids and Their Derivatives... 

Summary Phosfdiazene bases represent a new class of highly active non-ionic catalysts that rapidly polymerize cyclosiloxanes with equilibrium attained in very short reaction times at very low catalyst levels. To date, phosphazene base catalysts have been considered an academic curiosity because of the complicated and hazardous synthetic protocol used to prepare them. A facile synthetic process has been developed, which yields ionic phosphazene bases in three steps with an overall yield of qrproximately 75%. This is achieved through nucleophilic substitution of ionic phosphonitrilic chloride oligomers with secondary amines, followed by anion exchange. These ionic phosphazenes were found to exhibit similar reactivity in the ring-opening polymerization of cyclosiloxanes to that of the non-ionic phosphazene base. 

Imidazole reactivity was fully covered in CHEC-I, and only a brief summary is included here. The neutral molecule is Jt-excessive, being subject to electrophilic attack at N-3, less readily at C-4(5), and seldom at C-2. In benzimidazole electrophiles preferentially attack N-3 and the benzene ring carbons. Nucleophilic substitution reactions usually require some form of electron withdrawal elsewhere in the system, with displacements of groups at C-2 often favored. Imidazolium species are naturally more susceptible to nucleophilic attack, and they only undergo electrophilic substitutions with difficulty (e.g. nitration, sulfonation). The corresponding imidazole anions, when they can form, are highly reactive towards electrophiles. 

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