Hydrogen bonding nucleophilic substitution

Once in the organic phase, cyanide ion is only weakly solvated and is far more reactive than it is in water or ethanol, where it is strongly solvated by hydrogen bonding. Nucleophilic substitution takes place rapidly. 

Alkyl methacrylates, hydrolysis of polymeric ester functionality, 259 Aluminum-hydrogen bond, nucleophilic substitution, 264 Amines alkylation, 28 benzyl-group cleavage, 25 Aminomethylation chloromethylated polymers, 19 Deltfpine reaction, 19 Anionic polymerization advantages, 85... 

The benzyltrimethylammonium ion migrates to the butyl bromide phase, carrying a cyanide ion along with it. Once in the organic phase, cyanide ion is only weakly solvated and is far more reactive than it is in water or ethanol, where it is strongly solvated by hydrogen bonding. Nucleophilic substitution takes place rapidly. The benzyltrimethylammonium bromide formed in the substitution step returns to the aqueous phase, where it can repeat the cycle. 

These heterocyclization reactions provide initial products with a functionality (3 to the heteroatom, except for cases where a proton is the electrophile. Synthetic applications often depend upon further transformation of this functionality. Useful transformations include replacement by hydrogen, elimination to form a ir-bond, nucleophilic substitution, and substitution via radical intermediates. These reactions will be discussed only when understanding the cyclization step requires inclusion of the functional group transformation. 

The Pd—C cr-bond can be prepared from simple, unoxidized alkenes and aromatic compounds by the reaction of Pd(II) compounds. The following are typical examples. The first step of the reaction of a simple alkene with Pd(ll) and a nucleophile X or Y to form 19 is called palladation. Depending on the nucleophile, it is called oxypalladation, aminopalladation, carbopalladation, etc. The subsequent elimination of b-hydrogen produces the nucleophilic substitution product 20. The displacement of Pd with another nucleophile (X) affords the nucleophilic addition product 21 (see Chapter 3, Section 2). As an example, the oxypalladation of 4-pentenol with PdXi to afford furan 22 or 23 is shown. 

Solvent Effects on the Rate of Substitution by the S 2 Mechanism Polar solvents are required m typical bimolecular substitutions because ionic substances such as the sodium and potassium salts cited earlier m Table 8 1 are not sufficiently soluble m nonpolar solvents to give a high enough concentration of the nucleophile to allow the reaction to occur at a rapid rate Other than the requirement that the solvent be polar enough to dis solve ionic compounds however the effect of solvent polarity on the rate of 8 2 reactions IS small What is most important is whether or not the polar solvent is protic or aprotic Water (HOH) alcohols (ROH) and carboxylic acids (RCO2H) are classified as polar protic solvents they all have OH groups that allow them to form hydrogen bonds... 

Benzylic carbon-hydrogen bonds in compounds such as methylpentafluoro-benzene, fluoromethylpentafluorobenzene, and difluoromethylpentafluoroben-zene are not capable of metalation by butyllithium Instead nucleophilic substitution of the para fluorines occurs m each example [55] (equation 13)... 

A bifunctional reagent such as ethanolamine can favor ortho substitution of azines due to hydrogen bonding as in 62. With a bifunctional nucleophile such as ethylene glycol anion, facilitation of... 

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. 

Nucleophilic substitution of pyridines is discussed in previous sections in relation to the following cyclic transition states (Section II, B, 5), hydrogen bonding and cationization (Section II, C), the leaving group (Section II, D,) and the effect of other substituents (Section II, E) and of the nucleophile (Section II, F). 

Various nucleophilic reactions of polysubstituted 5-halopyri-midines are described in Section II,E,2,e with postulates to explain the degree of reactivity. For pyrimidine derivatives, the effect of the following on nucleophilic substitution is included in earlier sections hydrogen bonding and cationization in Section II, C, the leaving group in Section II, D, and the nucleophile in Sections II,E,2,e and II, F. 

Nucleophilic substitution of as-triazines is discussed in relation to hydrogen bonding and the effects of the leaving group and of other nuclear substituents in Sections II,C,D, and E, respectively. 

In bicyclic azines, as in the monocyclic azines already discussed, the faster of two nucleophilic substitutions proceeds via the transition state which has the lower free energy (with respect to the reactants) due to the stabilizing effects of resonance, hydrogen bonding, or electrostatic attractions. Different nucleophiles and different leaving... 

The reactivities of 4- and 2-halo-l-nitronaphthalenes can usefully be compared with the behavior of azine analogs to aid in delineating any specific effects of the naphthalene 7r-electron system on nucleophilic substitution. With hydroxide ion (75°) as nucleophile (Table XII, lines 1 and 8), the 4-chloro compound reacts four times as fast as the 2-isomer, which has the higher and, with ethoxide ion (65°) (Table XII, lines 2 and 11), it reacts about 10 times as fast. With piperidine (Table XII, lines 5 and 17) the reactivity relation at 80° is reversed, the 2-bromo derivative reacts about 10 times as rapidly as the 4-isomer, presumably due to hydrogen bonding or to electrostatic attraction in the transition state, as postulated for benzene derivatives. 4-Chloro-l-nitronaphthalene reacts 6 times as fast with methanolic methoxide (60°) as does 4-chloroquinoline due to a considerably higher entropy of activation and in spite of a higher Ea (by 2 kcal). ... 

Specific alterations of the relative reactivity due to hydrogen bonding in the transition state or to a cyclic transition state or to electrostatic attraction in quaternary compounds or protonated azines are included below (cf. also Sections II, B, 3 II, B, 5 II, C and II, F). A-Protonation is often reflected in an increase in JS and therefore the relative reactivity can vary with the significance of JS in controlling the reaction rate. Variation can also result from rate determination by the second stage of the SjjAr2 mechanism or from the intervention of thermodynamic control of product formation. Variation in the rate and in the reactivity pattern of polyazanaph-thalenes will result when nucleophilic substitution [Eq. (10)] occurs only on a covalent adduct (408) of the substrate rather than on its aromatic form (400). This covalent addition is prevented by any 4-... 

The nucleophilic substitution of quinoline as affected by cationiza-tion and hydrogen bonding is discussed in Section II, C, by the leaving group and other substituents in Sections II, D and II, E, respectively, and in Section III, A, 2, and by the nucleophile in Section II, F. 

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