Radical cations chemical properties

Chemical Properties. Higher a-olefins are exceedingly reactive because their double bond provides the reactive site for catalytic activation as well as numerous radical and ionic reactions. These olefins also participate in additional reactions, such as oxidations, hydrogenation, double-bond isomerization, complex formation with transition-metal derivatives, polymerization, and copolymerization with other olefins in the presence of Ziegler-Natta, metallocene, and cationic catalysts. All olefins readily form peroxides by exposure to air. 

Our studies showed that i) substitution of an exocyclic amino group of dG is effective in modulating the chemical properties of dG toward one-electron oxidation, and ii) decomposition of the guanine radical cation was effectively suppressed near dphG. These results indicate that dphG is a prototype of nucleosides functioning as an intrinsic antioxidant of duplex DNA toward one-electron oxidation. 

The most intriguing difference between the chemical properties of cyclopolysilanes and those of cycloalkanes is the ability of the former to form either anion or cation radicals upon one-electron reduction or oxidation, respectively. For example, the cyclic pentamer (Mc2Si)5 is reduced to the corresponding radical anion by sodium-potassium alloy in diethyl ether [see eqn (4.1) in Section 4.1.3], whereas the hexamer (Me2Si)6 is oxidised by aluminium trichloride in dichlor-omethane to the corresponding cation radical. In both cases the EPR spectra of the radical ions can be interpreted in terms of a-electron delocalisation over the entire polysilane ring (see Section 10.1.4.1). In this respect, the cyclosilanes resemble aromatic hydrocarbons rather than their aliphatic analogues. 

An updated book on organic radical ions3 comprises an extensive (presumably almost complete) set of hyperfine data and summarizes methods for their generation. Another book concentrates on chemical properties of radical ions4. Valuable information on timescales and the energetics leading to the dimerization of radical anions and cations (and neutral radicals) based on tetracyanoethylene, tetracyanoquinodimethane, substituted benzoquinones (DDQ and chloranil) as acceptors and octamethylbiphenylene is reported by Kochi and coworkers5. 

The gas-phase ionization of 2,4,6-tribromobenzene in the presence of m-fluoropyridine afforded the A -aryI -m-fluoropyridinc adduct from which the biradical cation was generated by loss of two bromine radicals.232 This biradical species was isolated and characterized using Fourier transform ion cyclotron resonance (FT-ICR) mass spectrometry and its chemical properties are discussed. FT-ICR was also used to isolate and characterize the products of electron ionization of fluorinated acetyl compounds, which included a biradical anion.233... 

By doping a primary catalyst component with lower-valent metal cations, additional oxygen vacancies will be created which facilitate the incorporation of electrophilic oxygen species chemisorbed on the surface into the bulk where they will not oxidize adsorbed methyl radicals. Also, the promoter oxide should be basic, not be reducible, oxidizablc, or easily volatiz-ablc. It should form a mixed oxide with the main component which may be possible if the ionic radii arc similar. According to these rules, the expert system proposes as potential catalyst components combinations of substances with appropriate chemical and physico-chemical properties (Table 2). Many of these systems already have been described in the literature... 

Figure 2.30 Representation of the asymmetric unit of [Nd(L )4(H20)][(TTF—CH=CH—Py+)] 2-The radical cation donors are drawn as balls and sticks the paramagnetic anionic coordination complexes of Nd(III) are drawn as capped sticks [23d], (Reprinted with permission from F. Pointillart, O. Maury, Y. Fe Gal, S. Golhen, O. Cador and F. Ouahab, 4-(2-Tetrathiafulvalenyl-ethenyl)pyridine (TTF—CH=CH—py) radical cation salts containing poly(P-diketonate) rare earth complexes synthesis, crystal structure, photoluminescent and magnetic properties, Inorganic Chemistry, 48, 7421-7429, 2009. 2009 American Chemical Society.)...

Structure-reactivity relationship. This chapter is not a comprehensive review of the published work on radiation-induced chemical oxidation of benzene derivatives, nor does it cover redox properties and energetics of radical cations of substituted benzenes. The latter aspects have already been reviewed by Jonsson " earlier. In a series of papers,Jonsson and co-workers have clearly shown correlations between substituent pattern and redox properties of radical cations of substituted benzenes. Further, it has been shown by them that the product pattern is governed by the charge distribution on the radical cation and the electron density distribution on the corresponding substituted benzene. This chapter is an overview of the work carried out on radiation-induced oxidation of substituted benzenes with emphasis on the contribution to the area from our research group. 

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