Pyridine electrophilic addition

The reactivity of a remarkable electronically unsaturated tantalum methyli-dene complex, [p-MeCgH4C(NSiMe3)2]2Ta( = CH2)CH3, has been investigated. Electrophilic addition and olefination reactions of the Ta = CH2 functionality were reported. The alkylidene complex participates in group-transfer reactions not observed in sterically similar but electronically saturated analogs. Reactions with substrates containing unsaturated C-X (X = C, N, O) bonds yield [Ta] = X compounds and vinylated organic products. Scheme 117 shows the reaction with pyridine N-oxide, which leads to formation of a tantalum 0x0 complex. ... 

Electrophilic addition to 9-vinylcarbazole occurs in the Markovnikov sense, thus hydrogen chloride,hydrogen bromide,chlorine, and bromine in carbon tetrachloride, and iodine chloride in pyridine are recorded as adding with initial electrophilic attack at the methylene. Mercuric acetate in methanol gave 9-(2-acetoxymercuri-l-methoxyethyl)carbazole. Although 9-vinylcarbazole gave an iodohydrin, comparable reaction with methanolic sodium hypochlorite led to 9-(2-chlorovinyl)carbazole. Catalytic reduction of the latter produced 9-(2-chloroethyl)carbazole. Tri-phenyltin hydride gave 96. ... 

Bromination of pyridine is much easier than chlorination. Vapour phase bromination over pumice or charcoal has been studied extensively (B-67MI20500) and, as with chlorination, orientation varies with change in temperature. At 300 °C, pyridine yields chiefly 3-bromo-and 3,5-dibromo-pyridine (electrophilic attack), whilst at 500 °C 2-bromo- and 2,6-dibromo-pyridine predominate (free radical attack). At intermediate temperatures, mixtures of these products are found. Similarly, bromination of quinoline over pumice at 300 °C affords the 3-bromo product, but at higher temperatures (450 °C) the 2-bromo isomer is obtained (77HC(32-1)319). Mixtures of 3-bromo- and 3,5-dibromo-pyridine may be produced by heating a pyridine-bromine complex at 200 °C, by addition of bromine to pyridine hydrochloride under reflux, and by heating pyridine hydrochloride perbromide at 160-170 °C (B-67MI20500). 

Participation of the pyridine nitrogen in electrophilic additions has been reported245. The cyclization of Z and E isomers 155 and 156 mediated by various electrophiles (MCPBA, PhSeX, NBS, I2) turned out to be stereospecific the diastereoselectivity varies with the nature of the electrophilic reagent246. 

In contrast to the ease of N-functionalization, shown in Scheme 1, the triazolopyridine nucleus is resistant to direct nuclear oxidation or electrophilic additions. Electrophilic additions will occur on aryl substituents for example, nitration of l-phenyltriazolo[4,5-c]pyridine (26) and sulfonation of 2-phenyl-2i/-triazolo[4,5-6]pyridine (28) occur exclusively in the para position of the phenyl ring <34LA(514)279, 38MI 710-01). Nuclear functionalization was observed when l-( -butyl)-5-methyl-tri-azolo[4,5-c]pyridinium iodide (30) was treated with potassium ferricyanide to afford triazolopyridin-4-one (31), as shown in Scheme 2. Similarly, the iodide (30) is converted by either phosphorus oxychloride-phosphorus pentachloride, or bromine or nitric acid to 7-substituted triazolopyridin-4-ones (32) <37LA(529)288>. 

While 2-ami no-2//-triazolopyridines (74) have not been reported, the close structural features found in the pyridino[4,5]benzo-l,3a,6,6a-tetraazapentalenes (see Section 7.10.5.1) provide an excellent framework to study the differential electronic effects between the benzene system and the pyridine system. In general, all the isomeric pentalenes show greater ease for electrophilic addition... 

This chapter describes in general terms the types of reactivity found in the typical six- and five-membered aromatic heterocycles. We discuss electrophilic addition (to nitrogen) and electrophilic, nucleophilic and radical substitution chemistry. This chapter also has discussion of orf/to-quinodimethanes, in the heterocyclic context. Organometallic derivatives of heterocycles, and transition metal (especially palladium)-catalysed chemistry of heterocycles, are so important that we deal with these aspects separately, in Chapter 4. Emphasis on the typical chemistry of individual heterocyclic systems is to be found in the summary chapters (7, 10, 13, 15, 19 and 23), and a more detailed examination of typical heterocyclic reactivity and many more examples for particular heterocyclic systems are to be found in the chapters - Pyridines Reactions and Synthesis , etc. 

The formal replacement of a CH in benzene by N leads to far-reaching changes in typical reactivity pyridines are much less susceptible to electrophilic substitution than benzene and much more susceptible to nucleophilic attack. However, pyridine undergoes a range of simple electrophilic additions, some reversible, some forming isolable products, each involving donation of the nitrogen lone pair to an electrophile, and thence the formation of pyridinium salts which, of course, do not have a counterpart in benzene chemistry at all. The ready donation of the pyridine lone pair in this way does not destroy the aromatic... 

Many of the lessons to be learnt apply to both 1,3- and 1,2-azoles, though the direct linking of the two heteroatoms in the latter has a snbstantial inductive influence, altering properties in degree. Thus the 1,2-azoles tend to be less nucleophilic and less basic at the imine nitrogen than their 1,3-isomers. That such electrophilic additions occur readily, illustrates, as for pyridine, that an imine nitrogen lone pair is not involved in the aromatic sextet of electrons. 

H-D exchange via an electrophilic addition process, such as operates for benzene, does not take place with pyridine. A special mechanism allows selective exchange at the two a-positions in DCI-D2O or even in water at 200 °C, the key species being an ylide formed by 2/6-deprotonation of the 1//-pyridinium cation (see also section 5.12). ... 

Whether a Lewis acid is capable of initiating these polymerizations by itself was tested, with the aid of an early discovery. It has been known for some time that hindered bases like crowded pyridine derivatives exhibit specificity toward reactions with protons. Such bases might be used to discriminate between two types of initiating mechanisms encountered with Lewis acids. The base will not interfere with direct electrophilic additions of the Lewis acids to the monomer. On the other hand, it should prevent an initiation process by protons from taking place. If both pathways are operative, then the pyridine derivatives can only quench the protonic initiation and will offer a means of assessing the relative importance of each process. 

Preparative Method the title compound with 5-configuration can be made from (5)-mandelic acid following a four-step reaction sequence reduction (LiAlH4), selective tosylation (TsCl/Bu2SnO/Et3N), displacement (NaSPh), and acetylation (Ac20/pyridine). The racemic isomer can be prepared by electrophilic addition to st3rene. ... 

Heavily fluonnated aminobenzenes, pyridines, and pyrimidines are diazotized in strong-acid media Solid sodium nitrite added directly to the fluonnated amine dissolved in 80% hydrofluonc acid, anhydrous hydrogen fluoride, or (1 1 wt/wt) 98% sulfuric acid in (86 14 wt/wt) acetic and propionic acids affords the electrophilic fluoroarenediazonium ion Addition of an electron rich aromatic to the resultant diazonium solution gives the fluoroareneazo compound [10 II] (equa tions 9 and 10)... 

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