Quinoline radical anion

With radical ions, the dimerization equilibrium is strongly influenced by the solvation and association of radical ions with counter ions. It has been shown that the free ions dimerize much more slowly than do the respective contact ion pairs e.g., the quinoline radical anion does not dimerize in the powerfully solvating hexamethylphosphoramide, but it does dimerize rapidly in tetra-hydrofuran (160). Thus, two equilibria should be distinguished (160), viz. 

The equilibrium between radical-anion and dimer for pyridine and quinoline has been examined in a number of aprotic solvents. Radical-anions of pyridine dimer-ise rapidly in liquid ammonia in tire presence of alkali metal ions [15] In hex-amethylphosphoramide with alkali metal counter ions, the monomer is detectable in an equlibrium concentration [16], The monomeric species can be stabilised by substituents and 2- or 4-cyanopyridines give radical-anions which persist in liquid ammonia while 3-cyanopyridine radical-anion dimerises with a rate constant of 2 x 10 [17], Quinoline radical-anion is stable in hexamelhylphosphoramide [16] but in liquid ammonia it dimerises irreversibly [18]. 

Irradiation of lomefloxacin 271 in dilute neutral aqueous solution (in which it exists as a zwitter ion) in Pyrex-filtered 500 W medium pressure mercury (Helios Italquartz) at 17°C gave pyrrolo[3,2,l-(/ ]quinoline 272 (99JOC5388). Under this condition, reductive defluorination via a radical anion took place. This study is important because of the phototoxicity of the fluorinated compounds which could be used as antibacterials (Scheme 49). 

The sonochemistry of the other alkali metals is less explored. The use of ultrasound to produce colloidal Na has early origins and was found to greatly facilitate the production of the radical anion salt of 5,6-benzo-quinoline (225) and to give higher yields with greater control in the synthesis of phenylsodium (226). In addition, the use of an ultrasonic cleaning bath to promote the formation of other aromatic radical anions from chunk Na in undried solvents has been reported (227). Luche has recently studied the ultrasonic dispersion of potassium in toluene or xylene and its use for the cyclization of a, o-difunctionalized alkanes and for other reactions (228). 

The ESR hyperfine coupling constants have been established experimentally (67MI20402) for the pyridinyl radical (134 R = H) and deuterated analogues, produced by y irradiation of a solid solution of pyridine in ethanol at 77 K, but the signs of the couplings are not known experimentally and are made solely on the basis of Huckel MO calculations. INDO MO calculations on this radical, together with the radical anions of quinoline, isoquinoline and acridine h ve also been carried out (740MR(6)5). 

Crooks, R. M. and Bard, A. J. (1988b) Electrochemistry in near-critical and supercritical fluids. Part V. The dimerization of quinoline and acridine radical anions in ammonia from 70°C to 150°C. J. Electroanal. Chem. 240, 253-279. 

Reactions with reductively and oxidatively generated [26] perfluoroalkyl radicals have also been successfully used for perfluoroalkylation of aromatic compounds (Scheme 2.103). For the reductive initiation, the single electron transfer (SET) necessary for formation of the radical anion priming the reaction sequence can be provided either by a reductive reagent (for example HOCH2SO2Na) [27] or by an electron-rich aromatic substrate itself [28]. The oxidatively induced variant enables the perfluoroalkylation of more electron-deficient aromatic substrates, for example quinoline. 

Radical anions from aromatics which are intermediates in Birch-type reductions were prepared sonochemically. Pyridine, quinoline, and indole sonicated with lithium in THF in the presence of trimethylsilyl chloride yield the bis-TMS dihydroaromatics, which can be reoxidized, by air or benzoquinone, in a rapid and easy method to prepare silyl-substituted aromatics. The procedure was extrapolated to phenols (Eq. 6). ... 

An alternative route to PPS involves polymerization of p-halothiophenols as A-B monomers (26). Copper 4-bromothiophenoxide polymerizes to PPS in quinoline or quinoline/pyridine mixtures at temperatures of 200 - 230 C and atmospheric pressures (31). Mechanistic studies support that polymerization of the copper salt proceeds by an Sj radical-anion mechanism at the early stages of the reaction and may contribute in the later stages of polymerization as well (32). Debromination has been observed as a molecular weight lim-... 

Zoltewicz and Oestreich (1973) employed sodium methylate to accelerate the reaction between 4-bromo-iso-quinoline and sodium thiophenolate. In this case, the CHjO ion acts as a competing electron donor with respect to the PhS ion. On electron transfer to the substrate, thiophenolate converts into the phenylthiyl radical and then to diphenyldisulhde. Diphenyldisulfide is inactive in further transformations. The methylate ions generate the anion-radicals of the substrate, thus preserving the greater part of the thiophenolate for use in substitution. The observed rate of thioarylation and the yield of 4-phenylthio-iso-quinoline increase in the presence of sodium methylate. Azobenzene inhibits the action of sodium methylate. Scheme 5.7 summarizes what has been mentioned. 

Quinoline derivatives have been substituted by nucleosides <94JCS(P1)2931> and by ert-butyl groups <95JOC(60)5390> via radical substitution reactions. Palladium-catalyzed cross coupling method has been used to couple quinoline triflates with acetylene <95T(51)3737>. 4-Quinolones, in contrast to 2-quinolones, react with peroxodisulfate anions in aqueous base to form 3-hydroxyquinolines via the 3-sulfate ester <95JCR(S)164>. 

The first reduction wave for phenanthridine jV-oxide in dimethyl-formamide (at 25°) appears at — 1.774 (vs. s.c.e.) in good agreement with the HMO energy of the lowest vacant orbital277 a mechanism for the reduction has been proposed.278 No esr signal could be detected during controlled-potential electrolysis at the appropriate potential, perhaps because of the relative instability of the anion radical. This behavior, which is paralleled by isoquinoline, contrasts sharply with that of the oxides of other polynuclear N-heteroaromatic systems (e.g., quinoline and acridine).277... 

Analogously, although the enhanced reactivity of quinoline derivatives (relative to pyridine counterparts) in nucleophilic additions such as the formation of pseudobases and Reissert compounds probably relates to the relatively lower energy of the LUMO in the quinoline derivatives, the radicals from these heterocycles, in which the corresponding orbitals are singly occupied, are anionic thus, reactivity toward nucleophiles is also unlikely to be important. 

The reactivities of several azanaphthalene anion-radicals, alter polaro-graphic generation, are discussed by van der Meer.122,123 This includes the radicals of quinazoline and cinnoline whose ESR spectra do not appear to have been reported. The stability of carbon-halogen bonds in various azine anion-radicals, including quinoxaline and quinoline, has been discussed, as has the reactivity of quinoline anions toward alkyl halides.92,182 In the latter reaction alkylation occurs at the 1,2- and 2,4-positions. Heteroarylation of a range of electron-rich substrates by azine anion-radicals has been reported.183 No mechanism is implied in the available abstract, but the apparent electrophilicity on the part of the azine anions is surprising. 

---