Electron transfer between an organic

Fig. 10.2 Electron transfer between an organic molecule and an acceptor or donor...

The extent of electron transfer between an organic substrate and a metal is a complex function of the metal s sublimation energy (Sx) and ionization... 

Clays may also promote electron transfer between adsorbed organic reactants. This process is termed redox disproportionation if the electron transfer occurs between two identical species. The formation of p-cymene and p-menthene from p-menthene is an example (56). In the presence of polymers were the main products. 

Since electroanalytical response ultimately depends on electron transfer between an electrode material and a solution species, any intervening layers or films are of obvious consequence. As noted earlier, carbon materials are prone to adsorption, and it is not trivial to prepare carbon surfaces that are not contaminated with adsorbed layers, usually of adventitious organic impurities. In order to avoid poor or irreproducible responses from carbon electrodes, the user must either find conditions where surface impurities have negligible or reproducible effects on the process of interest, or prepare the carbon surface in a way that avoids surface films. As is evident from the history of electroanalytical chemistry since the DME, surface cleanliness is a major issue with solid electrodes, no less so for carbon. 

Numerous studies [295-300] have shown that the rate of electron transfer between an electrogenerated radical anion (mediator) and a halogenated organic compound (substrate) increases as the difference between the standard potentials for reduction of the precursor of the mediator and for reduction of the substrate decreases. 

The process that occurs arises from an electron transfer between an electron donating organic compound and a color developing material such as crystal violet lactone or benzoyl leucoauramine dyes. The phenolics act as coating materials. 

Nitrate reductases (NaR) with an iron-sulfur center are used for nitrate conversion. Generally, nitrate is enzymatically reduced and NaR is in the oxidized form, which can be electrochemically reduced. However, the direct electron transfer between an enzyme and an electrode is strongly limited due to the fact that (1) the distance between the electrode surface and the redox active site of the enzyme, which is normally inside the globular protein, is large and (2) the orientation of donor to acceptor sites depends on the method of the immobilization of the enzyme at the electrode.Thus, low molar mass redox mediators including qui-nones, metal complexes, ferricyanide, derivatives of ferrocene, and organic redox dyes " have been used to facilitate the electron transfer between electrode and enzyme (Fig. 11.5). 

Many complexes of metals with organic ligands absorb in the visible part of the spectrum and are important in quantitative analysis. The colours arise from (i) d- d transitions within the metal ion (these usually produce absorptions of low intensity) and (ii) n->n and n n transitions within the ligand. Another type of transition referred to as charge-transfer may also be operative in which an electron is transferred between an orbital in the ligand and an unfilled orbital of the metal or vice versa. These give rise to more intense absorption bands which are of analytical importance. 

At present, several stable photocatalytic systems for production of hydrogen from water and organic compounds are made of semiconducting oxides and suitable proton reducing catalyzer. An efficient electron transfer between inorganic semiconductor and bacterial hydrogenase was shown to result in hydrogen photoproduction. 

Ru(NH3)6a+ 3+) to the gold surface (4 5). The unique anisotropy of the organized monolayer provides an opportunity to explore the effect of both orientation and distance on electron transfer between a molecule and a metal electrode (6-9). 

It is tempting to relate the thermodynamics of electron-transfer between metal atoms or ions and organic substrates directly to the relevant ionization potentials and electron affinities. These quantities certainly play a role in ET-thermo-dynamics but the dominant factor in inner sphere processes in which the product of electron transfer is an ion pair is the electrostatic interaction between the product ions. Model calculations on the reduction of ethylene by alkali metal atoms, for instance [69], showed that the energy difference between the M C2H4 ground state and the electron-transfer state can be... 

Generally these globular dendritic architectures offer several advantages over other kinds of organic polymers, such as the full exposure of the catalytic centers to the environment. In contrast to linear or cross-Hnked polymeric supports, which can partially hide catalytic centers, the functional groups are located on the surface of the dendritic nanoparticle and diffusional Hmitations are less relevant Furthermore the close proximity of the catalytic centers on the surface of the dendritic polymer can enhance the catalytic activity by multiple complexation or even cooperativity. This behavior is described as positive dendritic effect. However, in some cases a negative dendritic effect was observed, which is caused by an undesired interaction or electron transfer between the neighboring catalytic centers on the surface of the dendrimer [70]. 

To understand features of oxidative one-electron transfer, it is reasonable to compare average energies of formation between cation- and anion-radicals. One-electron addition to an organic molecule is usually accompanied by energy decrease. The amount of energy reduced corresponds to... 

All these data verify that in real systems, the rate of electron transfer between components of a conductive chain is high. There are states of a mixed valence. Enhanced electric conductivity and other unusual physical properties are widespread among those inorganic or coordination compounds that contain metals in intermediate -valence states. In cases of organic metals, nonstoi-chiometric donor/acceptor ratios provide even better results. For example, the salt of (TTF)i (Br)oj composition displays an electric conductivity of 2 X 10 cm while (TTF)i(Br)i salt does not... 

Electrons are transferred singly to any species in solution and not in pairs. Organic electrochemical reactions therefore involve radical intermediates. Electron transfer between the electrode and a n-system, leads to the formation of a radical-ion. Arenes, for example are oxidised to a radical-cation and reduced to a radical-anion and in both of these intermediates the free electron is delocalised along the 7t system. Under some conditions, where the intermediate has sufficient lifetime, these electron transfer steps are reversible and a standard electrode potential for the process can be measured. The final products from an electrochemical reaction result from a cascade of chemical and electron transfer steps. 

A second mechanism proposes electron transfer between the photogenerated hole (h + ) and an adsorbed organic substrate (Eq. 66) [92],... 

Electron transfer reactions have been characterized with much more rigor in inorganic chemistry than with organic molecules. Marcus has provided the principal description relating the kinetics and thermodynamics of electron transfer between metal complexes (1). The Marcus theory, a computationally simple approach with good predictive power, is an empirical treatment which uses thermodynamic parameters and spectroscopic measurements to calculate kinetic data. It assumes that bimolecular electron transfer reactions occur in three stages as shown in Scheme 1 (1) formation of the precursor complex, (2) electron transfer, and (3) solvation of the redox pair. 

Steenken S (1988) Electron transfer between radicals and organic molecules via addition/elimina-tion. An inner-sphere path. In Rice-Evans C, Dormandy T (eds) Free radicals chemistry, pathology and medicine. Richelieu Press, London, pp 53-71 Steenken S (1989) Purine bases, nucleosides and nucleotides Aqueous solution redox chemistry and transformation reactions of their radical cations e and OH adducts. Chem Rev 89 503-520 Steenken S (1992) Electron-transfer-induced acidity/basicity and reactivity changes of purine and pyrimidine bases. Consequences of redox processes for DNA base pairs. Free Radical Res Commun 16 349-379... 

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