Intermolecular reactions formate anions

Intermolecular photoreaction of an aryl halide with another aromatic compound may lead to the formation of biaryls. In this section several examples of such reactions will be discussed. In some cases, information concerning the reaction mechanism is available but the depth to which mechanisms have been investigated varies greatly. In many cases aryl radicals formed by homolysis of the carbon-halogen bond are the reactive species. Such radicals may also be produced via electron transfer, followed by departure of halide anion. In some cases aryl cations have been proposed as intermediates. Intermolecular bond formation may also be preceded by charge transfer within an exciplex or by formation of radical ion pairs. 

Other reports on the [3+2] cycloadditions of indoles and nitrile oxides focus on intermolecular reactions. For example, Gribble [80] has investigated the reaction of (phenylsulfonyl)-2-(tri-n alkylstannyl)indoles 169 with tetranitromethane to give the novel isoxazolo[5,4-b]indole derivative 173 (Scheme 49). The mechanism cascade is thought to proceed through the degradation of the dinitromethyl anion to a nitrile oxide 171, followed by a 1,3-dipolar cycloaddition to form a nitroindole intermediate 172 and subsequent loss of nitrous acid or SnR3N02. Treatment of the isoxazole 173 with base then leads to the formation of the oxindole tautomer 175 as the major product. 

Unfortunately, anionic ROP promoted by metal alkoxides is often accompanied by significant intra- and intermolecular transesterification and termination reactions, resulting in the formation of cyclic oligomers and broadening the molecular weight distribution. The occurrence of side reactions along anionic ROP is ascribed to the high ionicity of the metal alkoxide bond. 

An efficient and also elegant synthesis of the active anti-influenza A virus indole alkaloid hirsu-tine 67 is performed by an inter-intermolecular anionic-pericyclic three- component domino reaction followed by solvolysis and hydrogenation (scheme 13).[261 The synthetic sequence developed by us contains first a Knoevenagel condensation of enantiopure 61 and 62 with the formation of the... 

Anionic polymerization of -caprolactone has been studied in several laboratories and it was found that considerable amounts of oligomers were found as by-products.— — We have studied the formation of oligomers in the anionic polymerization of 6-capro-lactone by gpc technique.A In view of the very facile intra- and intermolecular transesterification reactions in this system- -, the product distribution seems very interesting to check the validity of the thermodynamic equilibrium. 

The reaction temperature was also found to influence the efficiency of the linking reaction. As summarized in Table I, the increase in reaction temperature from 25°C to 45°C resulted in an increase in star-branch polymer formation. Qualitatively, it was also observed that the formation of vinylbenzylanion occurred more rapidly at the elevated temperatures. Apparently, the increased reaction temperatures render the intermolecular attack on the pendant vinyl groups by the polydienyllithium anions more favorable in comparison to the intramolecular intra-nodule alkylbenzyl anion-vinyl group reaction (Table I on the following page). 

Reaction of Cytochrome cimu with Tris(oxalato)cobalt(III) The cytochrome c protein was also used as reductant in a study of the redox reaction with tris (oxalato)cobalt(III).284 Selection of the anionic cobalt(III) species, [Conl(ox)3]3 was prompted, in part, because it was surmised that it would form a sufficiently stable precursor complex with the positively charged cyt c so that the equilibrium constant for precursor complex formation (K) would be of a magnitude that would permit it to be separated in the kinetic analysis of an intermolecular electron transfer process from the actual electron transfer kinetic step (kET).2S5 The reaction scheme for oxidation of cyt c11 may be outlined ... 

---