Nucleophilic substitution accelerate

Nucleophilic substitution by azide ion on an alkyl halide (Sections 8 1 8 13) Azide ion IS a very good nucleophile and reacts with primary and secondary alkyl halides to give alkyl azides Phase transfer cata lysts accelerate the rate of reaction... 

One significant difference between nitrocarboaromatics and aromatic azines is the tendency of the activating center of the latter to react with electrophiles or compounds capable of hydrogen bonding, thereby accelerating nucleophilic substitution. 

When a positively charged substituent such as the trimethylam-monio group is anywhere on the ring, but most effectively when it is ortho to the leaving group, it can favorably affect the entropy of activation with anionic nucleophiles and accelerate reaction. A recent example of reagent-substituent interaction is the electrophilic substitution of 2-carboxybiphenyl, nitration (non-polar solvent) of which occurs only at the 2 -position and not the 4 -position and has been postulated to be due to the interaction of the nitronium ion with the carboxyl group. 

Nucleophilic displacement reactions One of the most common reactions in organic synthesis is the nucleophilic displacement reaction. The first attempt at a nucleophilic substitution reaction in a molten salt was carried out by Ford and co-workers [47, 48, 49]. FFere, the rates of reaction between halide ion (in the form of its tri-ethylammonium salt) and methyl tosylate in the molten salt triethylhexylammoni-um triethylhexylborate were studied (Scheme 5.1-20) and compared with similar reactions in dimethylformamide (DMF) and methanol. The reaction rates in the molten salt appeared to be intermediate in rate between methanol and DMF (a dipolar aprotic solvent loiown to accelerate Sn2 substitution reactions). 

Although phase-transfer catalysis has been most often used for nucleophilic substitutions, it is not confined to these reactions. Any reaction that needs an insoluble anion dissolved in an organic solvent can be accelerated by an appropriate phase transfer catalyst. We shall see some examples in later chapters. In fact, in principle, the method is not even limited to anions, and a small amount of work has been done in transferring cations, radicals, and molecules. The reverse type of phase-transfer catalysis has also been reported transport into the aqueous phase of a reactant that is soluble in organic solvents. ... 

A long series of studies of aromatic nucleophilic substitution included the kinetics of reactions of l-chloro-2,4-bis(trifluoromethylsulfonyl)benzene, 3-nitro-4-chlorophenyl trifluoromethyl sulfone and 2-chlorophenyl trifluoromethyl sulfone with sodium methox-ide or ammonia in methanol . The SO2CF3 group was found to have an enormous accelerating effect, in accord with the value of 1.65, based on the dissociation of anilinium ion. Further examples of the promotion of nucleophilic aromatic substitution by fluoro-substituted sulfonyl groups are given by Yagupol skii and coworkers . 

The solvent dependence of the reaction rate is also consistent with this mechanistic scheme. Comparison of the rate constants for isomerizations of PCMT in chloroform and in nitrobenzene shows a small (ca. 40%) rate enhancement in the latter solvent. Simple electrostatic theory predicts that nucleophilic substitutions in which neutral reactants are converted to ionic products should be accelerated in polar solvents (23), so that a rate increase in nitrobenzene is to be expected. In fact, this effect is often very small (24). For example, Parker and co-workers (25) report that the S 2 reaction of methyl bromide and dimethyl sulfide is accelerated by only 50% on changing the solvent from 88% (w/w) methanol-water to N,N-dimethylacetamide (DMAc) at low ionic strength this is a far greater change in solvent properties than that investigated in the present work. Thus a small, positive dependence of reaction rate on solvent polarity is implicit in the sulfonium ion mechanism. 

We discussed earlier (p. 135) that nucleophilic substitution at the sulfonyl group of the cyclic, five-membered sultone [55] occurs over 10J times faster than for an open chain aryl arenesulfonate and that this large rate acceleration... 

Ho and coworkers" have observed that the addition of small amounts of solid KCN (0.2 equivalents) can effectively accelerate the formation of hydroxamic acids 112 from methyl esters 111 (Scheme 58). The authors suggested that this reaction proceeds through an acylcyanide intermediate followed by nucleophilic substitution by 50% aqueous hydroxylamine at room temperature. The use and advantage of this methodology have been demonstrated for both solution-phase and solid-phase applications. 

Catalysis of Nucleophilic Substitution Reactions. It has been known for many years that metal ions with a strong affinity for halogens will accelerate the reactions of alkyl halides with nucleophiles (Equation 3). It is assumed that the polarization of the carbon-halogen bond, as a consequence of coordination,... 

Nucleophilic displacement of 2-chloro-3-phenylquinoxaline with methylamine at 100°-150° and with sodium phenoxide in excess of phenol of 100° gives the expected 2-methylamino- and 2-phenoxy-3-phenylquinoxalines.155 2-Chloroquinoxaline and its 3-phenyl derivative undergo ring closure with aminoacetaldehyde dimethylacetal to an imidazo[l,2-a]quinoxaline.136 Nucleophilic substitution of 2-chloro-quinoxaline with hydroxide ion in water is accelerated by cationic micelles and retarded by anionic micelles. These results were correlated with reactions of l-chloro-2,4-dinitrobenzene, and the characteristics of their transition states were discussed.137... 

By the same token that aza substituents retard electrophilic substitution, so they accelerate nucleophilic substitution,19,20 40 41 particularly when positively charged. In an interesting study based on this type of reactivity, the equilibrium 16 = 17 has been investigated,85 and this and the rate of subsequent ring opening leading to substituted anils of glutaconic aldehyde found to correlate with o. ... 

Scheme 23 Microwave-accelerated nucleophilic substitution in tryptase inhibitor synthesis...

Ju and Varma envisioned that the nucleophilic substitution reaction of alkyl halides with amines may be accelerated by microwave energy because of their polar nature [88]. An environmentally friendly synthesis of tertiary amines via direct JV-alkylation of primary and secondary amines by alkyl halides under microwave irradiation was developed (Scheme 21), that pro-... 

The first step involves the formation of a pyridinium ion by reaction of a pyrylium ion with a primary amine the second step (dequaternization) has been studied more extensively than the first (amine + pyrylium). This important work on dequaternization deserves special mention because, besides the value for synthesis and understanding of steric acceleration, it sheds new light on the mechanism of aliphatic nucleophilic substitution (84CSR47). 

In an attempt to combine the two approaches of accelerating organic reactions, a nucleophilic substitution reaction has been carried out in a microemulsion in the presence of a phase transfer agent [51]. The aim of the work was to investigate if a combination of the two approaches would give a reaction rate higher than that obtained in either the microemulsion approach or in a two-phase system using phase transfer catalysis. 

An important group of reactions pertaining to this class is the nucleophilic substitution of a chloro or a nitro group at the benzylic position of p-nitrocumyl derivatives similarly to the SRN1 ring substitution (Sect. 2.1.4) the process is accelerated by light absorption (possibly on the part of a nucleophile-substrate ground state complex) and proceeds via a chain mechanism (Scheme 36) [192-194]... 

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