Definition electrophilic intermediates

We consider as dihydro derivatives those rings which contain either one or two 5p3-hybridized carbon atoms. According to this definition, all reactions of the aromatic compounds with electrophiles, nucleophiles or free radicals involve dihydro intermediates. Such reactions with electrophiles afford Wheland intermediates which usually easily lose H+ to re-aromatize. However, nucleophilic substitution (in the absence of a leaving group such as halogen) gives an intermediate which must lose H and such intermediates often possess considerable stability. Radical attack at ring carbon affords another radical which usually reacts further rapidly. In this section we consider the reactions of isolable dihydro compounds it is obvious that much of the discussion on the aromatic heterocycles is concerned with dihydro derivatives as intermediates. 

The intermediate 1,5-dicarbonyl compounds of type 24 (Scheme 1) can be constructed not only on the basis of meta-alkoxy-substituted benzyl ketones (C4 + Ci synthesis, Section II,C), but also under definite conditions starting from aryl ketones (C2 + C3 synthesis). Thus, in a molecule of acylveratrole derivatives of type 79, the excess of 7r-electron density due to the presence of two ortho-methoxy groups allows such compounds to be involved in electrophilic substitutions with benzoin (73URP2 74KGS1575). 

As pointed out by Stork and coworkers in their definitive 1963 paper3, the reaction with electrophilic alkenes is especially successful since reaction at nitrogen is reversible. Reaction at the /2-carbon is (usually) rendered irreversible by, in the case of cyclohexanone enamines, internal proton transfer of the axial C-/2 proton to the anionic centre of the initially formed zwitterionic intermediate (34), under conditions of stereoelectronic control (Scheme 22). When this intramolecular proton transfer cannot occur in aprotic solvents, or when the product produced in protic solvents is a stronger carbon acid than adduct 35 (i.e. when Z = COR, N02), then carbon alkylation is also reversible and surprising changes in the regioselectivity of reaction may be observed (vide infra see also Section VI.D and Chapter 26). Cyclobutanes (36) and, in the case of a,/ -unsaturated... 

It seems appropriate to inquire whether or not it is possible to carry out other Michael reactions and, generally, other nucleophilic additions to unsaturated compounds as a sequence of kinetically independent steps using one s choice of nucleophiles and electrophiles The answer is definitely yes . A rationale similar to that used to describe the Robinson annulation provides us with the key to how this goal may be attained. First of all, the initial step of the reaction, addition of the nucleophilic component across a double (or triple) bond, needs to be carried out in the absence of the external electrophiles (preferably in aprotic solvents). Secondly, a carbanionic intermediate, incipiently formed at this step, requires sufficient stabilization to survive as a chemical entity under... 

Aromatic iodides (3,287). The definitive paper on the synthesis of aromatic iodides by the reaction of arylthallium dilrifluoroacetates with potassium iodide has been published. Four procedures have been developed. I) Thallalion is carried out as usual and then an aqueous solution of potassium iodide is added directly. 2) The intermediate arylthallium ditrifluoroacctatc is isolated and then treated with potassium iodide. 3) For acid-sensitive. substrates solid TTFA in acetonitrile is used for thallalion. 4)These methods are unsuccessful with highly reactive compounds such as naphthalene and diphenyl. In such cases molecular iodine is used as the electrophilic reagent and TTFA is used as oxidant for the hydrogen iodide formed in the reaction. 

Many chemical reactions involve a catalyst. A very general definition of a catalyst is a substance that makes a reaction path available with a lower energy of activation. Strictly speaking, a catalyst is not consumed by the reaction, but organic chemists frequently speak of acid-catalyzed or base-catalyzed mechanisms that do lead to overall consumption of the acid or base. Better phrases under these circumstances would be acid promoted or base promoted. Catalysts can also be described as electrophilic or nucleophilic, depending on the catalyst s electronic nature. Catalysis by Lewis acids and Lewis bases can be classified as electrophilic and nucleophilic, respectively. In free-radical reactions, the initiator often plays a key role. An initiator is a substance that can easily generate radical intermediates. Radical reactions often occur by chain mechanisms, and the role of the initiator is to provide the free radicals that start the chain reaction. In this section we discuss some fundamental examples of catalysis with emphasis on proton transfer (Brpnsted acid/base) and Lewis acid catalysis. 

At this point, aiming to formulate a loeal version for electrophilicity a working local softness expression is needed to this end, by inspecting the Eq. (4.212) on its intermediate form, while remembering the local-to-global ratio definition for Fukui function according with Eq. (4.196) here under the form... 

The Stolle reaction is thought to occur via a typical mechanism for amide formation from an amine and acid chloride, followed by Friedel-Crafts alkylation or acylation. No definitive mechanistic work has been performed on this reaction, but incorporating the mechnistic understandings of two steps provides a firm basis for understanding the mechanism of this reaction. Formation of the mono-amide from oxalyl chloride and aniline provides intermediate 4, which in the presence of AICI3 undergoes intramolecular electrophilic aromatic substitution to the desired 2,3-dioxindole (isatin) 7 via intermediates 5 and 6. 

---