Scope of Nucleophile

It should be emphasized that the wide scope of nucleophilic aromatic photosubstitution does not imply that it will work indiscriminately with any combination of aromatic compound and nucleophile. On the contrary, there are pronounced selectivities. The general picture now arising shows a field with certainly as much variability and diversification as chemists, in the course of growing experience, have learned to appreciate in the area of classical (thermal) aromatic substitution. It is one of the aims of this article to contribute to a description and understanding of the various reaction paths and mechanisms of nucleophilic aromatic photosubstitution, hopefully to the extent that valuable predictions on the outcome of the reaction in novel systems will become feasible. 

A further example of the use of a chiral anion in conjunction with a chiral amine was recently reported by Melchiorre and co-workers who described the asymmetric alkylation of indoles with a,P-unsaturated ketones (Scheme 65) [212]. The quinine derived amine salt of phenyl glycine (159) (10-20 mol%) provided the best platform with which to perform these reactions. Addition of a series of indole derivatives to a range of a,P-unsaturated ketones provided access to the adducts with excellent efficiency (56-99% yield 70-96% ee). The substrates adopted within these reactions is particularly noteworthy. For example, use of aryl ketones (R = Ph), significantly widens the scope of substrates accessible to iminium ion activation. Expansion of the scope of nucleophiles to thiols [213] and oximes [214] with similar high levels of selectivity suggests further discoveries will be made. 

Chemical, as opposed to cathodic, delivery of electrons to the triple bond has been accomplished in various ways. The conventional fl/7//-selective reductions of alkynes by dissolved metals is still important--", but new reagents and solvents have widened the scope of nucleophilic reductions (Table 9). Indeed, an understanding of the mechanistic options has made for greater flexibility different initiation and entry/ departure of participants is now possible. 

Palladium-catalyzed oxidative allylic C-H functionalization provides attractive methods for the transformations of olefins, and their utility can be further enhanced by the development of more effective ways to use molecular oxygen (or air) to promote the catalytic cycle. The results outlined in this chapter summarize significant progress in the coupling reaction between terminal alkene and various types of nucleophiles. Further studies will be directed to explorations of the scope of nucleophilic reagents and olefins, and elucidation of the mechanisms of those reactions. Such studies will play an important role in the ongoing development of Pd-catalyzed C-H bond activations. 

Coordination of an arene to an electrophilic transition metal complex fragment renders the arene susceptible to nucleophilic addition. In the preceding chapter the scope of nucleophiles, questions of regioselectivity and reversibility, and aromatic substitution via this methodology were discussed. In the present chapter we will focus on the transformation of arenes into functionalized alicyclic molecules via the same cyclohexadienyl intermediates. 

The use of an ArS group as electroauxiliaries expands the scope of nucleophiles, the in situ use of carbon nucleophiles. Thus, ArS-substituted carbamates can be anodically oxidized in... 

This realization led me to study related possible intermolecular electrophilic reactions of saturated hydrocarbons, Not only protolytic reactions but also a broad scope of reactions with varied electrophiles (alkylation, formylation, nitration, halogenation, oxygenation, etc.) were found to be feasible when using snperacidic, low-nucleophilicity reaction conditions. 

The behavior of such activated halides as alkylating agents under Friedel-Crafts conditions expands the scope of the synthesis. Aluminum chloride enhances the electrophilic character of the a,/S-unsaturated carbonyl system and permits the nucleophilic attachment of the aromatic addendum (Y ) to the carbon bearing the positive charge, with displacement of halogen [Eq. (5)]. Thus,... 

In the previous review (91YGK205, 99H1157), we reported that l-hydroxy-4-nitroindole forms active ester derivatives by reaction with carboxylic acids, which can be applied to acylation of various nucleophiles. To expand the scope of the reaction and obtain novel fungicidal compounds, an attempt has been made to prepare derivatives of wasabi phytoalexin 109 (98P1959). 

The scope of this reaction is similar to that of 10-21. Though anhydrides are somewhat less reactive than acyl halides, they are often used to prepare carboxylic esters. Acids, Lewis acids, and bases are often used as catalysts—most often, pyridine. Catalysis by pyridine is of the nucleophilic type (see 10-9). 4-(A,A-Dimethylamino)pyridine is a better catalyst than pyridine and can be used in cases where pyridine fails. " Nonbasic catalysts are cobalt(II) chloride " and TaCls—Si02. " Formic anhydride is not a stable compound but esters of formic acid can be prepared by treating alcohols " or phenols " with acetic-formic anhydride. Cyclic anhydrides give monoesterified dicarboxylic acids, for example,... 

When aromatic nitro compounds are treated with cyanide ion, the nitro group is displaced and a carboxyl group enters with cine substitution (p. 854), always ortho to the displaced group, never meta or para. The scope of this reaction, called the von Richter rearrangement, is variable. As with other nucleophilic aromatic substitutions, the reaction gives best results when electron-withdrawing groups are in ortho and para positions, but yields are low, usually < 20% and never > 50%. 

As so far described, online searching is faster then searching the printed CA, but gives us essentially the same information. The scope of the online method is much greater than that, for it allows us to combine words, in a number of ways. One such way is by the use of the terms AND, NOT, and OR. If we search AMBIDENT AND NUCLEOPHILE, we will get something like this... 

Subsequently, the scope of the reaction was extended to N-nucleophiles 82. Because the inherent basicity of the substitution products 83 imposed some problems concerning catalyst decomposition, the addition of catalytic amoimts of piperidine hydrochloride (pip-HCl) proved to be necessary. Under optimized reaction conditions different aromatic amines 82 were allylated with almost exclusive regioselectivites in favor of the ipso substitution products 83 (eq. 1 in Scheme 20) [64]. 

Recently, the scope of the allylic substitution has been extended to sulfinate salts 84 to obtain allylic sulfones 85. Due to solubility problems of both nucleophile 84 and carbonate leaving group, a polar solvent mixture of DMF and 2-methoxyethanol had to be employed, which limits the reaction to the use of a phosphine ligand. Thus, various aryl sulfinates 84 and functionalized carbonates 81 could be converted to the corresponding allylic sulfones 85 with good to excellent yields and regioselectivites and complete retention of stereochemistry (eq. 2 in Scheme 20) [65]. 

It has been found that a number of bidentate ligands greatly expand the scope of copper catalysis. Copper(I) iodide used in conjunction with a chelating diamine is a good catalyst for amidation of aryl bromides. Of several diamines that were examined, rra s-yV,yV -dimethylcyclohexane-l,2-diamine was among the best. These conditions are applicable to aryl bromides and iodides with either ERG or EWG substituents, as well as to relatively hindered halides. The nucleophiles that are reactive under these conditions include acyclic and cyclic amides.149... 

---