Electron donor character, anionic

The replacement of two CH groups in benzene by a neutral NR, O or S introduces into the new ring an electron-donating heteroatom. This electron-donor character is accentuated in the pyrrole anion where N is introduced. Thus the five-membered rings with one heteroatom are electron rich (rr-excessive), and the chemistry of pyrrole, furan and thiophene is dominated by this effect and is again considered together as a whole in Part 3. 

Y, this bond is at first going to be a two-center, three-electron bond (H5C6.. Y). This process of nucleophile addition can and must be viewed as an inner-sphere electron transfer. In other words, formation of the new bond is connected with a transfer of the electron to phenyl radical. Therefore, the good electron donor character of Y is necessary for this step eventually to lead to the efficient formation of (H5C6Y), i.e., the product anion radical. Galli and Gentili (1998) have evaluated the thermodynamic driving force (TDDF) of the nucleophile/radical addition step. With respect to this step, they classified a nucleophile... 

It is now well established that a variety of organic molecules such as polynuclear aromatic hydrocarbons with low ionization energies act as electron donors with the formation of radical cations when adsorbed on oxide surfaces. Conversely, electron-acceptor molecules with high electron affinity interact with donor sites on oxide surfaces and are converted to anion radicals. These surface species can either be detected by their electronic spectra (90-93, 308-310) or by ESR. The ESR results have recently been reviewed by Flockhart (311). Radical cation-producing substances have only scarcely been applied as poisons in catalytic reactions. Conclusions on the nature of catalytically active sites have preferentially been drawn by qualitative comparison of the surface spin concentration and the catalytic activity as a function of, for example, the pretreatment temperature of the catalyst. Only phenothiazine has been used as a specific poison for the butene-1 isomerization on alumina [Ghorbel et al. (312)). Tetra-cyaonoethylene, on the contrary, has found wide application as a poison during catalytic reactions for the detection of active sites with basic or electron-donor character. This is probably due to the lack of other suitable acidic probe or poison molecules. 

Surface Superbasic Sites of One-electron Donor Character. - The reaction of alkali metal with anionic vacancies on the oxide surfaces (equation 1) leads to the creation of colour centres of F type. The transfer of one electron from the alkali metal atom to an anionic vacancy is the reason for the formation of these defects. The largest quantities of this type of active centre are obtained by evaporation of the alkali metal onto an oxide surface calcined at about 1023 K, at which temperature the largest quantity of anionic vacancies is formed. Oxide surfaces calcined at such high temperatures contain only a small quantity of OH groups ca. 0.5 OH per 100 for MgO and 0.8 OH per 100 for AI2O3), so their role in the reaction is small and the action of alkali metal leads selectively to the creation of defects of the electron in anionic vacancy type. The evidence for such a reaction mechanism is the occurrence of specific colours in the oxide. Magnesium oxide after deposition by evaporation of sodium, potassium, or a caesium turns blue, alumina after sodium evaporation becomes a navy blue in colour, and silica after sodium evaporation becomes violet-brown in colour. ... 

Many compounds with an electron donor character are reported to have an accelerating effect on the anionic polymerizations. 

The color center formed according to eq. (1) is of strong one-electron donor character, while the other sites formed by eqs. (2) —(4) are of strong electron-pair donating character. The increases in basic strength are caused by the introduction of an electron from the alkali metal to the hole trapped on the O -anion for eq. (2), and by replacement of an H atom by a more electropositive alkali metal atom for eqs. (3) and (4). 

The HO—LU interaction came early to the notice of theoreticians. Hiickel 74> pointed out the role of LU in the alkaline reduction of naphthalene and anthracene. Moffitt 75> characterized the formation of S03, SO2CI2, etc. by the reactions of SO2 as an electron donor with the S-atom-localiz-ing character of HO MO. Walsh 76) considered that the empirical result of producing nitro compounds in the reaction of the nitrite anion with the carbonium ion should be attributed to the HO of the NO2 anion which is localized at the nitrogen atom. 

Consequently, the relative contribution of xenodeborylation to fluorine addition across the C=C double bond and the ratio of the [BF4] to [XCF=CFBF3] anions depends on the electron-withdrawing character of X (acidity of the borane) and the actual ratio of XeF2 (fluoride donor) to XCF=CFBF2 (fluoride acceptor). 

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