Nucleophiles categories

The use of carbon nucleophiles in Michael-type addition reactions with pteridine and its derivatives leads to a quite complicated and divergent pattern. These reactions are strongly dependent on the nature of the carbon nucleophile and can be divided into various categories. 

Certain bifunctional nucleophiles allow cyclization after ring opening. The formation of 2-thiazolium salts (71JHC40S) and the analogous production of 2-amino-2-thiazolines (191) from aziridines and thiocyanic acid fall into this category (72JOC4401). 

The preparation of esters can be classified into two main categories (1) carboxy-late activation with a good leaving group and (2) nucleophilic displacement of a caiboxylate on an alkyl halide or sulfonate. The latter approach is generally not suitable for the preparation of esters if the halide or tosylate is sterically hindered, but there has been some success with simple secondaiy halides and tosylates (ROTs, DMF, K2CO3, 69-93% yield). ... 

For the other broad category of reaction conditions, the reaction proceeds under conditions of thermodynamic control. This can result from several factors. Aldol condensations can be effected for many compounds using less than a stoichiometric amount of base. Under these conditions, the aldol reaction is reversible, and the product ratio will be determined by the relative stability of the various possible products. Conditions of thermodynamic control also permit equilibration among all the enolates of the nucleophile. The conditions that permit equilibration include higher reaction temperatures, protic solvents, and the use of less tightly coordinating cations. 

The reactions of NSF3 have been investigated in considerable detail. They can be classified under the following categories (a) reactions with electrophiles (b) addition to the SN triple bond and (c) reactions with nucleophiles. Some examples of these different types of behaviour are discussed below. 

The notion of concurrent SnI and Sn2 reactions has been invoked to account for kinetic observations in the presence of an added nucleophile and for heat capacities of activation,but the hypothesis is not strongly supported. Interpretations of borderline reactions in terms of one mechanism rather than two have been more widely accepted. Winstein et al. have proposed a classification of mechanisms according to the covalent participation by the solvent in the transition state of the rate-determining step. If such covalent interaction occurs, the reaction is assigned to the nucleophilic (N) class if covalent interaction is absent, the reaction is in the limiting (Lim) class. At their extremes these categories become equivalent to Sn and Sn , respectively, but the dividing line between Sn and Sn does not coincide with that between N and Lim. For example, a mass-law effect, which is evidence of an intermediate and therefore of the SnI mechanism, can be observed for some isopropyl compounds, but these appear to be in the N class in aqueous media. 

The greater the contribution of 4 to the transition state, the more firmly the system is placed in the N category likewise a large contribution from 5 is characteristic of the Lim category. Bentley and Schleyer state that the essential difference between the SnI and Sn2 mechanisms depends upon whether nucleophilic attack... 

In discussing base catalysis it will prove convenient to adopt, at the outset, a distinction first proposed by Bunnett and Garst22, who noted that the observed cases of catalysis in nucleophilic aromatic substitution could be broadly divided into two categories. The classification was in terms of the relative rates of the catalyzed and uncatalyzed reactions. Since all of the systems could be accommodated empirically by eqn. (4),... 

If one limits the consideration to only that limited number of reactions which clearly belong to the category of nucleophilic aromatic substitutions presently under discussion, only a few experimental observations are pertinent. Bunnett and Bernasconi30 and Hart and Bourns40 have studied the deuterium solvent isotope effect and its dependence on hydroxide ion concentration for the reaction of 2,4-dinitrophenyl phenyl ether with piperidine in dioxan-water. In both studies it was found that the solvent isotope effect decreased with increasing concentration of hydroxide ion, and Hart and Bourns were able to estimate that fc 1/ for conversion of intermediate to product was approximately 1.8. Also, Pietra and Vitali41 have reported that in the reaction of piperidine with cyclohexyl 2,4-dinitrophenyl ether in benzene, the reaction becomes 1.5 times slower on substitution of the N-deuteriated amine at the highest amine concentration studied. 

Finally, the reaction of 19b with potassium fluoride in the presence of a crown-ether phase-transfer agent118 to yield the sulfonyl fluoride 67 and diphenylacetylene119 belongs to the same category in which a nucleophile (F in this case) attacks the electrophilic sulfur of the sulfone group (equation 19). 

In Part 2 of this book, we shall be directly concerned with organic reactions and their mechanisms. The reactions have been classified into 10 chapters, based primarily on reaction type substitutions, additions to multiple bonds, eliminations, rearrangements, and oxidation-reduction reactions. Five chapters are devoted to substitutions these are classified on the basis of mechanism as well as substrate. Chapters 10 and 13 include nucleophilic substitutions at aliphatic and aromatic substrates, respectively, Chapters 12 and 11 deal with electrophilic substitutions at aliphatic and aromatic substrates, respectively. All free-radical substitutions are discussed in Chapter 14. Additions to multiple bonds are classified not according to mechanism, but according to the type of multiple bond. Additions to carbon-carbon multiple bonds are dealt with in Chapter 15 additions to other multiple bonds in Chapter 16. One chapter is devoted to each of the three remaining reaction types Chapter 17, eliminations Chapter 18, rearrangements Chapter 19, oxidation-reduction reactions. This last chapter covers only those oxidation-reduction reactions that could not be conveniently treated in any of the other categories (except for oxidative eliminations). 

In these reactions, diazonium salts are cleaved to aryl radicals, in most cases with the assistance of copper salts. Reactions 14-17 and 14-18 may also be regarded as belonging to this category with respect to the attacking compound. For nucleophilic substitutions of diazonium salts, see 13-17-13-20. 

Perhaps the most characteristic property of the carbon-carbon double bond is its ability readily to undergo addition reactions with a wide range of reagent types. It will be useful to consider addition reactions in terms of several categories (a) electrophilic additions (b) nucleophilic additions (c) radical additions (d) carbene additions (e) Diels-Alder cycloadditions and (f) 1,3-dipolar additions. 

Carbonyl-stabilized ylides and the cyano-stabiHzed ylides Ar3P=CHCN in spite of their low nucleophilicity are able to give stable complexes. By comparison, very few complexes involving the second category of ylides are known. However a new example has recently been described by reaction of the cyano-ylide 60 with palladium(II) to give the complex tra s-[PdCl2 CH(PTol3)CN 2] 61 (Scheme 24) [93]. 

Notice that tert-butoxide appears in both the second and third categories. Technically, it is a strong nucleophile and a strong base, so it belongs in the third category. But practically, tert-butoxide is stericaUy hindered, which prevents it from functioning as a nucleophile in most cases. Therefore, it is often used as a base, to favor E2 over Sn2. 

The third category contains reagents that are both strong nucleophiles and strong bases. These reagents include hydroxide (HO ) and alkoxide ions (RO ), and are generally used for bimolecular processes (Sn2 and E2). 

The simplest interpretation of equation (15) would assume a nucleophilic attack on Co(III) by OH-. This, however, would put OH in an extraordinary category of nucleophilicity. Garrick was the first to note that an alternative explanation for the role of OH was available. In the alternative, the conjugate base of the initial complex ammine is presumed to be formed in small amount and to function as the actual reactive species... 

In most of the hitherto known cationic domino processes another cationic process follows, representing the category of the so-called homo-domino reactions. In the last step, the final carbocation is stabilized either by the elimination of a proton or by the addition of another nucleophile, furnishing the desired product. Nonetheless, a few intriguing examples have been revealed in which a succession... 

Anionic domino processes are the most often encountered domino reactions in the chemical literature. The well-known Robinson annulation, double Michael reaction, Pictet-Spengler cyclization, reductive amination, etc., all fall into this category. The primary step in this process is the attack of either an anion (e. g., a carban-ion, an enolate, or an alkoxide) or a pseudo anion as an uncharged nucleophile (e. g., an amine, or an alcohol) onto an electrophilic center. A bond formation takes place with the creation of a new real or pseudo-anionic functionality, which can undergo further transformations. The sequence can then be terminated either by the addition of a proton or by the elimination of an X group. 

Base catalysis of ligand substitutional processes of metal carbonyl complexes in the presence of oxygen donor bases may be apportioned into two distinct classifications. The first category of reactions involves nucleophilic addition of oxygen bases at the carbon center in metal carbonyls with subsequent oxidation of CO to C02, eqns. 1 and 2 (l, 2). Secondly, there are... 

An intriguing reaction has been reported that does not exactly fit into the category of Michaelis-Arbuzov reaction but does involve nucleophilic attack of a neutral trivalent phosphorus for generation of a new C-P bond. Phenyl- and methyldichlorophosphine have been reported to attack the strained cyclopropane ring system of 1,3-dehy-droadamantane, overall adding P-Cl across the most strained bond of the ring system (Equation 3.5).140... 

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