Medium effects nucleophilic substitution

While looking for the optimum operating conditions of the effect of dimethylamine on p-chloroacetophenone, the technicians heated the medium at 234°C the reagents proportion in weight being 1/4.22. The medium detonated not long after. It is likely that this was an aromatic nucleophilic substitution reaction as follows ... 

Payne rearrangement. The Payne rearrangement2 of a primary cts-2,3-epoxy alcohol to a secondary 1,2-epoxy alcohol usually requires a basic aqueous medium, but it can be effected with BuLi in THF, particularly when catalyzed by lithium salts. As a consequence, the rearrangement becomes a useful extension of the Sharpless epoxidation, with both epoxides available for nucleophilic substitutions. Thus the more reactive rearranged epoxide can be trapped in situ by various organometallic nucleophiles. Cuprates of the type RCu(CN)Li are particularly effective for this purpose, and provide syn-diols (3).3... 

This reaction proceeds via the transition state illustrated in Fig. 10.2. An Sn2 reaction (second order nucleophilic substitution) in the rate limiting step involves the attack of the nucleophilic reagent on the rear of the (usually carbon) atom to which the leaving group is attached. The rate is thus proportional to both the concentration of nucleophile and substrate and is therefore second order. On the other hand, in an SnI reaction the rate limiting step ordinarily involves the first order formation of an active intermediate (a carbonium ion or partial carbonium ion, for example,) followed by a much more rapid conversion to product. A sampling of a and 3 2° deuterium isotope effects on some SnI and Sn2 solvolysis reactions (i.e. a reaction between the substrate and the solvent medium) is shown in Table 10.2. The... 

The mechanistic aspects of nucleophilic substitution reactions were treated in detail in Chapter 5 of Part A. That mechanistic understanding has contributed to the development of nucleophilic substitution reactions as importantl synthetic processes. The SN2 mechanism, because of its predictable stereochemistry and avoidance of carbocation intermediates, is the most desirable substitution process from a synthetic point of view. This section will discuss the role of SN2 reactions in the preparation of several classes of compounds. First, however, the important role that solvent plays in SN2 reactions will be reviewed. The knowledgeable manipulation of solvent and related medium effects has led to significant improvement of many synthetic procedures that proceed by the SN2 mechanism. 

The nucleophilic substitution of the reactive chlorine atoms in hexa- and dichloride clathrochelates by a series of aliphatic amines is very sensitive to the effects of the medium (primary, the solvent employed), and the trend of the reaction is determined to a great extent by the donor properties of the amines and the steric accessibility of the nucleophilic centre. The subsequent substitution reaction course and feasible reaction products in the case of hexachloride precursors are presented in Scheme 24. The stepwise-formed clathrochelate complexes are denoted according to the degree of the substitution of chlorine atoms by amine groups ... 

Most of the work concerned with micellar catalysis of nucleophilic substitution refers to reactions of the Aac2 and SN2 types and will not be reviewed here. To date only a few systems have been examined in which a micellar medium affects the partitioning of solvolytic reactions between unimolecular and bimolecular mechanisms. The effects of cationic (hexadecyltrimethylammonium bromide = CTAB) and anionic (sodium lauryl sulfate = NaLS) micelles on competitive SN1 and SN2 reactions of a-phenylallyl butanoate 193) have been investigated189. The rate of formation of the phenylallyl cation 194) is retarded by both surfactants probably as a consequence of the decreased polarity of the micellar pseudo phase. The bimolec-... 

Aqueous cationic micelles speed and anionic micelles inhibit bi-molecular reactions of anionic nucleophiles. Both cationic and anionic micelles speed reactions of nonionic nucleophiles. Second-order rate constants in the micelles can be calculated by estimating the concentration of each reactant in the micelles, which are treated as a distinct reaction medium, that is, as a pseudophase. These second-order rate constants are similar to those in water except for aromatic nucleophilic substitution by azide ion, which is much faster than predicted. Ionic micelles generally inhibit spontaneous hydrolyses. But a charge effect also occurs, and for hydrolyses of anhydrides, diaryl carbonates, chloroformates, and acyl and sulfonyl chlorides and SN hydrolyses, reactions are faster in cationic than in anionic micelles if bond making is dominant. This behavior is also observed in water addition to carbocations. If bond breaking is dominant, the reaction is faster in anionic micelles. Zwitterionic sulfobetaine and cationic micelles behave similarly. 

While this result confirmed the feasibility of the general approach, it did not precipitate wider exploration of dielectric medium effects. Recently, however, Wiberg et al. have incorporated the Onsager self-consistent reaction-field model into ab initio MO theory in an implementation which provides analytical gradients and second derivatives. The model considers just the dipole of the solute molecules and a spherical cavity whose radius is chosen for a given solute molecule from the molecular volume estimated at the 0.001 eB electron-density contour (B is the Bohr radius), plus an empirical constant 0.5 A to account for the nearest approach of solvent molecules [164]. Cieplak and Wiberg have used this model to probe solvent effects on the transition states for nucleophilic additions to substituted acetaldehydes [165]. For each... 

The indan-based a-amino acid derivatives can be synthesized by PTC. Kotha and Brahmachary [11] indicated that solid-liquid PTC is an attractive method that offered an effective way of preparing optically active products by chiral PTC. They found that ethyl isocyanoacetate can be easily bisalkylated in the presence of K2CO3 as the base and tetrabutylammonium hydrogen sulfate as the catalyst. The advantage of isolating water from the reaction medium is to avoid the formation of unwanted hydroxy compounds in the nucleophilic substitution reaction. If liquid-liquid PTC is applied in the system with the strong base NaOH and dichloromethane as the organic solvent, the formation of dihydroxy or cyclic ether can be observed. 

The effect of MWI on aromatic nucleophilic substitutions of activated haloben-zenes 181 with piperidine 180 (R = H) at atmospheric pressure and in a homogeneous medium was studied. The reactions were carried out in DMSO solvent and the products 182 were obtained in 9-93% yields within 6min-15h (Scheme 38). The reaction rates were 3.8-5.0 times faster than conventional heating with comparable yields (98TL2471). 

In the past, transition state theory(l) was typically used in a qualitative manner to explain the effect of medium changes on reaction rates. This approach reached its quintessence in the systematic prediction by Hughes and Ingold(2) of the effect of increased solvent polarity on the rates of various types of nucleophilic substitution reactions. Their classification of S 2 reactions... 

On the other hand, use of activity coefficients of transfer, instead of free energies of transfer, is an equivalent approach for examination of medium effects on reaction rates and equilibria. Parker has emphasized this alternative approach and the reader is referred to his writings, especially for medium effects in bimolecular nucleophilic substitution (Parker, 1969). 

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