Reduction reactions photochemical

Electrophilic attack Nucleophilic attack Free radical attack Photochemical reactions Oxidative and reductive reactions... 

Oxidation-reduction reactions in water are dominated by the biological processes of photosynthesis and organic matter oxidation. A very different set of oxidation reactions occurs within the gas phase of the atmosphere, often a consequence of photochemical production and destruction of ozone (O3). While such reactions are of great importance to chemistry of the atmosphere - e.g., they limit the lifetime in the atmosphere of species like CO and CH4 - the global amount of these reactions is trivial compared to the global O2 production and consumption by photosynthesis and respiration. 

As already mentioned, macular zeaxanthin comprises two stereoisomers, the normal dietary (3/(,37()-/caxanthin and (3f ,3 S)-zeaxanthin(=(meyo)-zeaxanthin), of which the latter is not normally a dietary component (Bone et al. 1993) and is not found in any other compartment of the body except in the retina. The concentration of (tneso)-zeaxanthin in the retina decreases from a maximum within the central fovea to a minimum in the peripheral retina, similar to the situation with (3/ ,37 )-zeaxanthin. This distribution inversely reflects the relative concentration of lutein in the retina and gave rise to a hypothesis (Bone et al. 1997) that (meso)-zeaxanthin is formed in the retina from lutein. This was confirmed by an experiment in which xanthophyll-depleted monkeys had been supplemented with chemically pure lutein or (3/ ,37 )-zeaxanthin (Johnson et al. 2005). (Meyo)-Zeaxanthin was exclusively detected in the retina of lutein-fed monkeys but not in retinas of zeaxanthin-fed animals, demonstrating that it is a retina-specific metabolite of lutein only. The mechanism of its formation has not been established but may involve oxidation-reduction reactions that are mediated photochemically, enzymatically, or both. Thus, (meso)-zeaxanthin is a metabolite unique to the primate macula. 

One possible strategy in the development of low-overpotential methods for the electroreduction of C02 is to employ a catalyst in solution in the electrochemical cell, A few systems are known that employ homogeneous catalysts and these are based primarily on transition metal complexes. A particularly efficient catalyst is (Bipy)Re[CO]3Cl, where Bipy is 2,2 bipyridine, which was first reported as such by Hawecker et al. in 1983. In fact, this first report concerned the photochemical reduction of C02 to CO. However, they reasoned correctly that the complex should also be capable of catalysing the electrochemical reduction reaction. In 1984, the same authors reported that (Bipy)Re[C013CI catalysed the reduction of C02 to CO in DMF/water/ tetraalkylammonium chloride or perchlorate with an average current efficiency of >90% at —1.25 V vs. NHE (c. —1.5V vs. SCE). The product analysis was performed by gas chromatography and 13C nmr and showed no other products. 

Pt2(P205H2) - (d8-d8), and Mo6Clft ( )6. Two- electron oxidations of Re2Cl and Pt2(P205H2)it have been achieved by one-electron acceptor quenching of the excited complexes in the presence of Cl, followed by one-electron oxidation of the Cl -trapped mixed-valence species. Two-electron photochemical oxidation-reduction reactions also could occur by excited-state atom transfer pathways, and some encouraging preliminary observations along those lines are reported. 

We have been investigating the oxidation-reduction reactions of the binuclear iron site in the protein matrix (27-32). The methemerythrin form contains both irons in the +3 oxidation state and can be reduced in two steps (by dithionite ion (27, 31), reduced methylviologen, and photochemically using a riboflavin/EDTA mixture (28)) to the deoxy form in which both irons are in the +2 oxidation state. The intermediate (semi-met), in which one iron is +3 and the other iron +2, has been... 

In conclusion, the flavoprotein systems isolated from the algae and the bacteria, have a good potential to play significant roles in pesticide degradation in aquatic environments. Such flavoprotein systems are active in degradation of xenobiotics both under aerobic and anaerobic conditions by promoting photochemical and reductive reactions. 

A reduction reaction induced by the absorption of a photon in the UV or visible wavelength range of light for example, the addition of one or more electrons to a photoexcited species and the photochemical hydrogenation of a substance. 

General chemical properties of triazolopyridines, such as oxidations, reductions, reaction with electrophiles, reactions with nucleophiles, homolytic reactions, ring-opening reactions, and photochemical reactions can be found in <2002AHC(83)2>. 

A major group of photochemical reduction reactions are oxidation-reduction processes. As typical examples, phenazine (CXXI) and alloxan (CXXIII) are reduced by ethanol to give dihydrophenazine (CXXIl)/ 2 and alloxantin (CXXIV).42 Isatin (CXXV) in the presence of ace-naphthene (CXXVI) is reduced to isatide (CXXVII).204 The photoreaction proceeds at the expense of the alcohol, or (CXXVI) acetaldehyde and acenaphthylene (CXXVIII), are formed as by-products respectively. The formation of CXXVII may be due to the interaction of CXXV with the intermediate oxindole (CXXIX). 

The photochemistry of aryl azides is quite complex, suggesting that the nitrene 14 may not be the only reactive intermediate and that insertion reactions may not be the only route to form photoconjugates.Although aryl nitrenes are much less susceptible to rearrangements than acyl nitrenes, they may still occur and lead to the formation of reactive intermediates such as azepines, which may go on to react with nucleophiles.[911 141 Addition of nitrenes to double bonds will generate azirines, while dimerization will produce azobenzenesJ11 Aryl azides are stable to most of the procedures used in the course of peptide synthesis except for reduction reactions. Non-photochemical reduction of aryl azides to the primary amines by thiols has been reported by Staros et al.[15]... 

The coupling of these photochemical and redox properties to water reduction reactions is now described. 

When C02 is bound between two metal centers, the ones that lose C02 most readily are the x2-r 2 and x2-r 3 complexes, in which one or two of the carboxylate oxygen atoms is (are) bound to a main group atom. These complexes are often intermediates in photochemical and electrochemical reduction reactions of C02 to CO. 

In certain cases, these rules, and most other definitions of oxidation and reduction, give counter-intuitive or contradictory results (12). For this reason, in part, few general works on organic reactivity place significant emphasis on reactions classified as oxidations or reductions (major exceptions are 13-17). Environmental chemists, on the other hand, still find it useful to classify organic transformations as oxidations or reductions (e.g., 2, 9,11, 18,19) because the environments in which they occur are often distinctive in this regard. The major (abiotic, non-photochemical) oxidation and reduction reactions that influence the environmental fate of organic contaminants are summarized in the two sections that follow. 

N2O can be utilized as an indirect marker of HNO formation. The dimerization of HNO has been studied both experimentally and theoretically since the 1960s, and several values for the rate constant have been offered [reviewed in (104,105)]. The current accepted value, determined by flash photolysis techniques at room temperature, is 8 x 106 M 1 s-1 (106), recently revised from 2 x 109 M-1 s-1 (107). Thus, the rate of this reaction requires that HNO be produced in situ by degradative, reductive, or photochemical methods. 

Besides the photochemical dissociation, ozone decays in oxidation-reduction reactions with different species. The stratospheric 03 reacts rapidly with nitric oxide and products of photodissociation of halogenated hydrocarbons (Figure 9.5). 

In order to account for such a mechanism, photochemical excitation of a semiconductor surface might induce the promotion of an electron from the valence band to the conduction band. Since relaxation of the high-energy electron is inhibited by the absence of intra-states, if the lifetime of this photo generated electron-hole pair is sufficiently long to allow the interfacial electron transfer from an accumulation site to an electron acceptor, as well as the interfacial electron transfer from an adsorbed organic donor to the valence-band hole, the irradiated semiconductor can simultaneously catalyze both oxidation and reduction reactions in a fashion similar to multifunctional enzymes reactions [232]. 

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