Reaction electron-deficient species

Reactions with Radicais and Electron-deficient Species... 

Reactions with Free Radicals and Other Electron Deficient Species... 

Reactions with Radicals and Electron-deficient Species Reactions at Surfaces 4.02.1.8.1 Carbenes and nitrenes... 

Reaction with radicals and electron-deficient species reaction at surfaces... 

Electron deficient species can attack the unshared electron pairs of heteroatoms, to form ylides, such as in the reaction of thietane with bis(methoxycarbonyl)carbene. The S —C ylide rearranges to 2,2-bis(methoxycarbonyl)thiolane (Section 5.14.3.10.1). A"-Ethoxycar-bonylazepine, however, is attacked by dichlorocarbene at the C=C double bonds, with formation of the trans tris-homo compound (Section 5.16.3.7). 

Perfluorinated carbonyl compounds, especially hexafluoroacetone, are highly electron-deficient species and react vigorously with a wide variety of HX nucleophiles The reaction of these ketones and of most polyfluonnated imines toward nucleophiles can be generahzed by the scheme shown m equation 1... 

Bis(trifluoromethyl)-substituted heterodienes are electron-deficient species They therefore react preferentially with electron-rich multiple bond systems to give [4+2] cycloadducts (Diels-Alder reaction with inverse electron demand) [238]... 

Gomez-Sainero et al. (11) reported X-ray photoelectron spectroscopy results on their Pd/C catalysts prepared by an incipient wetness method. XPS showed that Pd° (metallic) and Pdn+ (electron-deficient) species are present on the catalyst surface and the properties depend on the reduction temperature and nature of the palladium precursor. With this understanding of the dual sites nature of Pd, it is believed that organic species S and A are chemisorbed on to Pdn+ (SI) and H2 is chemisorbed dissociatively on to Pd°(S2) in a noncompetitive manner. In the catalytic cycle, quasi-equilibrium ( ) was assumed for adsorption of reactants, SM and hydrogen in liquid phase and the product A (12). Applying Horiuti s concept of rate determining step (13,14), the surface reaction between the adsorbed SM on site SI and adsorbed hydrogen on S2 is the key step in the rate equation. 

The pair of electrons in the n orbital are more diffuse and less firmly held by the carbon nuclei, and so more readily polarisable, than those of the a bond, leading to the characteristic reactivity of such unsaturated compounds. As the it electrons are the most readily accessible feature of the carbon-carbon double bond, we should expect them to shield the molecule from attack by nucleophilic reagents and this is indeed found to be the case (cf. p. 198, however). The most characteristic reactions of the system are, hardly surprisingly, found to be initiated by electron-deficient species such as X and X (radicals can be considered electron-deficient species as they are seeking a further electron with which to form a bond), cations inducing heterolytic, and... 

Reactions of 1,3,4-oxadiazoles at the ring atoms with radicals, carbenes, and nitrenes or with other electron-deficient species are rather uncommon. CHEC(1984) and CHEC-II(1996) have reported very few examples of such reactions concerning oxadiazolinones and oxadiazolinethiones. This situation has not changed. 

If trivalent phosphoms compounds are to be treated as electron-deficient species, then reactions of oxadiazoles with some Lewis acids should be reported here. 2-Phenyl-l,3,4-oxadiazole reacting with phosphoms trichloride in pyridine solution in the presence of triethylamine at low temperature furnished the respective dichlorophosphine and chlorophosphine, which were trapped by dimethylamine to give the corresponding amides. 2-Phenyl-l,3,4-oxadiazole also interacts over 24 h with the less reactive chlorodiphenylphosphine and dichlorophenylphosphine at room temperature to give phosphines (Scheme 14) <1999CHE1117>. These reactions of oxadiazoles resemble the behavior of 1-alkylimidazoles toward trivalent phosphorus derivatives. 

Reactions Involving Radicals, Electron-Deficient Species, Reducing Agents, and at... 

The only significant reactions that have appeared regarding this section involve reducing agents. For additional information on reactions with radicals and electron-deficient species, refer to CHEC(1984) <1984CHEC(6)513> and CHEC-II(1996) <1996CHEC-II(4)355>. 

The reactions of halogens and hydrogen halides with alkenes are electrophilic addition reactions. This means that the initial attack on the organic molecule is by an electron-deficient species that accepts a lone pair of electrons to form a covalent bond. This species is called an electrophile. In the case of the reaction with hydrogen bromide, the mechanism for the reaction is as shown. 

This reaction includes loss of CO prior to reaction of the rhodium fragment and the manganese fragment to form more reactive, electron deficient species, which we have omitted from the reaction equation. 

A reaction in which an electrophile participates in het-erolytic substitution of another molecular entity that supplies both of the bonding electrons. In the case of aromatic electrophilic substitution (AES), one electrophile (typically a proton) is substituted by another electron-deficient species. AES reactions include halogenation (which is often catalyzed by the presence of a Lewis acid salt such as ferric chloride or aluminum chloride), nitration, and so-called Friedel-Crafts acylation and alkylation reactions. On the basis of the extensive literature on AES reactions, one can readily rationalize how this process leads to the synthesis of many substituted aromatic compounds. This is accomplished by considering how the transition states structurally resemble the carbonium ion intermediates in an AES reaction. 

Reactions of 1,3,4-oxadiazoles at ring atoms with radicals or with electron-deficient species are uncommon. Diazoalkanes R R CN2 reacted with oxadiazolinethiones (22a R = H) to give A -alkyl... 

Reactions of 1,2,4-thiadiazoles with radicals and electron-deficient species are virtually unknown. Catalytic and dissolving metal reductions usually cleave the nucleus at its N—S bond by a reaction that may be regarded as the reverse of its synthesis by the oxidative cyclization of amidinothiono structures (Section 4.08.9.4). For example, reduction of the diamino compound (37) gives the amidinothiourea (38) from which it may be prepared by oxidation (Equation (8)). 

Reactions involving Radicals, Electron-deficient Species, Reducing Agents and at Surfaces... 

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