Substituent effects nucleophilic substitution

Displacements such as this show all the usual characteristics of electrophilic aromatic substitution (substituent effects, etc., see below), but they are normally of much less preparative significance than the examples we have already considered. In face of all the foregoing discussion of polar intermediates it is pertinent to point out that homolytic aromatic substitution reactions, i.e. by radicals, are also known (p. 331) as too is attack by nucleophiles (p. 167). 

In both electrophilic and nucleophilic substitutions, substituents already present in the pyridine ring have the effects which would be expected of them, on electronic grounds, upon both orientation and activation. One feature of orientation commonly observed is the tendency of a substituent at C(3> to direct substitution more to C(2) than to C(6). Interaction between the substituent and the substituting reagent, in which the nitrogen lone pair may play a part, has been held ss to be responsible for this effect (p. 173). Substituent-reagent interactions account for similar features of benzene substitutions234. 

Sekiguchi, S., Ohtsuka, L, Okada, K. Aromatic nucleophilic substitution. 11. Effects of ortho substituents on the rates of the Smiles rearrangements of ( 3-acetylamino)ethyl-2-X-4-Y-6-Z-l-phenyl ethers with potassium hydroxide in aqueous dimethyl sulfoxide. J. Org. Chem. 1979, 44(14), 2556-2560. 

As is broadly true for aromatic compounds, the a- or benzylic position of alkyl substituents exhibits special reactivity. This includes susceptibility to radical reactions, because of the. stabilization provided the radical intermediates. In indole derivatives, the reactivity of a-substituents towards nucleophilic substitution is greatly enhanced by participation of the indole nitrogen. This effect is strongest at C3, but is also present at C2 and to some extent in the carbocyclic ring. The effect is enhanced by N-deprotonation. 

The nucleophilic reactivity of 2-halogenothiazoles is strongly affected by the substituent effect, depending on the kind of substitution reaction. Positions 4 and 5 can be considered as meta and para , respectively, with regard to carbon 2 and to groups linked to it consequently, it is possible to correlate the reactivity data with Hammett s relationships. 

Regarding the substituent effect on reactivity of groups in positions 4 and 5 there is little information in the literature. The reactivity of halogen in position 5 seems to be increased when an amino group is present in position 2. Substitution products are easily obtained using neutral nucleophiles such as thiourea, thiophenols, and mercaptans (52-59). 

A nitro group behaves the same way m both reactions it attracts electrons Reaction is retarded when electrons flow from the aromatic ring to the attacking species (electrophilic aromatic substitution) Reaction is facilitated when electrons flow from the attacking species to the aromatic ring (nucleophilic aromatic substitution) By being aware of the connection between reactivity and substituent effects you will sharpen your appreciation of how chemical reactions occur... 

Because carbocations are key intermediates in many nucleophilic substitution reactions, it is important to develop a grasp of their structural properties and the effect substituents have on stability. The critical step in the ionization mechanism of nucleophilic substitution is the generation of the tricoordinate carbocation intermediate. For this mechanism to operate, it is essential that this species not be prohibitively high in energy. Carbocations are inherently high-energy species. The ionization of r-butyl chloride is endothermic by 153kcal/mol in the gas phase. ... 

In addition to steric effects, there are other important substituent effects which determine both the rate and mechanism of nucleophilic substitution reactions. It was... 

In spite of the potential complexity of the general problem, even when restricted to the reagent family of amines, the nucleophilicities of such series as meta- and pom-substituted pyridines and anilines appear to correlate very closely with the expected substituent effects and with the basicities. This has been verified in the following cases (i) The reaction of pyridines (R = H, m- andp-CHs) with 2-chloro-3-nitro-, 2-chloro-5-nitro-, and 4-chloro-3-nitro-pyridines. ... 

The least squares value for the p constant obtained by this procedure is +6.2 it wiU be obviously subject to change as more meta and epi substituents become available. Only the cata-NO group was excluded from the above plot because it causes a strongly enhanced resonance effect in nucleophilic substitution (Section IV,C, l,a) and an anomalous effect of uncertain origin in the dissociation of carboxylic acids. It can be assumed that the reaction constant for 4-chloro-... 

There is a difference of opinion about the net effect of resonance between the leaving group and an electron-attracting heterocycle, carbocycle, or substituent- This conjugation (101, 102) has been regarded as a deactivating influence on nucleophilic substitution since the C— Le bond is lower in polarity and higher in... 

Zahler and elaborated in a series of papers by Miller and co-workers and in Bunnett s publications, many of which are cited in Section I, D. It should be pointed out that the effects of substituents on nucleophilic substitutions show important differences from their effects on other reactions or on equilibria which involve competition for a lone-pair of electrons on another group or stabilization of negative charge on some atom of the reacting moiety. The cr-constants for nucleophilic substitutions differ from those determined in the latter work in that they show the response of the substituent to a strong demand for stabilization of negative charge on the substituent itself, especially by resonance. 

The effect of a substituent on aromatic nucleophilic substitution can vary with ... 

In aromatic nucleophilic substitution, two general effects of substituents are (2) to alter the ground state in a direction toward or away from the transition state and (2) to withdraw electrons from or donate them to the pentadienoid anion in the transition state and... 

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