Neutral resonance forms, effects

The electron could also be captured by the neutral to form a negative radical ion. However, electron capture (EC) is rather unlikely to occur with electrons of 70 eV since EC is a resonance process because no electron is produced to carry away the excess energy. [10] Thus, EC only proceeds effectively with electrons of very low energy, i.e., from thermal electrons up to a few electronvolts (Chap. 7.4). However, the formation of negative ions from electron impact may occur with analytes containing highly electronegative elements. 

An analytical structure-(hyper)polarizability relationship based on a two-state description has also been derived [49]. In this model a parameter MIX is introduced that describes the mixture between the neutral and charge-separated resonance forms of donor-acceptor substituted conjugated molecules. This parameter can be directly related to BLA and can explain solvent effects on the molecular hyperpolarizabilities. NMR studies in solution (e.g. in CDCl3) can give an estimate of the BLA and therefore allow a direct correlation with the nonlinear optical experiments. A similar model introducing a resonance parameter c that can be related to the MIX parameter was also introduced to classify nonlinear optical molecular systems [50,51]. 

The facile phase-transfer catalysed N-alkylation of phenylhydrazones provides an effective route to A-alkyl-A-phenylhydrazines, as shown in Scheme 5.5 [27]. Deprotonation of both the hydrazones and the triazenes leads to resonance stabilized anions. It is therefore highly probable that the alkylation occurs on the initially formed anions, instead of the neutral species, as indicated by the red colour imparted to the organic phase in the reactions of the triazenes, which results from the formation of the ion-pair [Q ArN=N-NAr]. 

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