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Thermal redox reactions

Similar photo-induced reductive dissolution to that reported for lepidocrocite in the presence of citric acid has been observed for hematite (a-Fe203) in the presence of S(IV) oxyanions (42) (see Figure 3). As shown in the conceptual model of Faust and Hoffmann (42) in Figure 4, two major pathways may lead to the production of Fe(II)ag i) surface redox reactions, both photochemical and thermal (dark), involving Fe(III)-S(IV) surface complexes (reactions 3 and 4 in Figure 4), and ii) aqueous phase photochemical and thermal redox reactions (reactions 11 and 12 in Figure 4). However, the rate of hematite dissolution (reaction 5) limits the rate at which Fe(II)aq may be produced by aqueous phase pathways (reactions 11 and 12) by limiting the availability of Fe(III)aq for such reactions. The rate of total aqueous iron production (d[Fe(aq)]T/dt = d [Fe(III)aq] +... [Pg.432]

Finally, some reactions can be considered as thermal redox reactions because they take place only at high temperatures. The equations below represent reactions of this type ... [Pg.108]

It is worth noting that similar processes could be in occurring with compounds 11, 19, 20 and 23 in which the oxidized sacrificial donor (e.g., TEA, DMA) deproto-nate to form a neutral radical species with good reducing power. While it is difficult to rule such a possibility out, MacDonnell and co workers have shown that the sing ly reduced version of compound 11, [(phen)2Run(tatpp )Run(phen)2]3+ can be iso lated and, when subject to photochemical reduction, cleanly undergoes the second reduction. Thus, while the overall reduction of 11 to 22 could include a thermal redox reaction, it does not require one. [Pg.150]

Fig. 8. Simplified free energy diagram of the photosynthetic electron transport chain (for details see Ref.27, 69X For the sake of simplicity only the reduced forms of the corresponding redox carriers are given. The electronic excitations are symbolized by thick open arrows, thermal redox reactions in the dark are indicated by thin arrows. Abbreviations Cyt fre(j = reduced cytochrome f, NADPH = reduced nicotinamide adenine dinucleotidphosphate, PCjgj = reduced plastocyanine, PQH2 = plastohydroquinone, Xf and X 320- are the reduced forms of the primary electron acceptor of C[ and Qj, respectively [see Eq. (14a, b)l, Y = watersplitting enzyme system... Fig. 8. Simplified free energy diagram of the photosynthetic electron transport chain (for details see Ref.27, 69X For the sake of simplicity only the reduced forms of the corresponding redox carriers are given. The electronic excitations are symbolized by thick open arrows, thermal redox reactions in the dark are indicated by thin arrows. Abbreviations Cyt fre(j = reduced cytochrome f, NADPH = reduced nicotinamide adenine dinucleotidphosphate, PCjgj = reduced plastocyanine, PQH2 = plastohydroquinone, Xf and X 320- are the reduced forms of the primary electron acceptor of C[ and Qj, respectively [see Eq. (14a, b)l, Y = watersplitting enzyme system...
Generation of radicals by redox reactions has also been applied for synthesizing block copolymers. As was mentioned in Section II. D. (see Scheme 23), Ce(IV) is able to form radical sites in hydroxyl-terminated compounds. Thus, Erim et al. [116] produced a hydroxyl-terminated poly(acrylamid) by thermal polymerization using 4,4-azobis(4-cyano pentanol). The polymer formed was in a second step treated with ceric (IV) ammonium nitrate, hence generating oxygen centered radicals capable of starting a second free radical polymeriza-... [Pg.751]

Though thermally stable, rhodium ammines are light sensitive and irradiation of such a complex at the frequency of a ligand-field absorption band causes substitution reactions to occur (Figure 2.47) [97]. The charge-transfer transitions occur at much higher energy, so that redox reactions do not compete. [Pg.120]

Hydroxy radicals are produced by redox reactions involving hydrogen peroxide (see 3.3.2.6.2). They can also be generated in organic solution by thermal decomposition of a-hydroperoxydiazenes (see 3.3.3.1). [Pg.128]

One of the earliest examples of this methodology involves the reaction of a polymeric anion (formed by living anionic polymerization) with molecular oxygen to form a polymeric hydroperoxide which can be decomposed either thermally or, preferably, in a redox reaction to initiate block polymer formation with a second monomer (Scheme 7.25). However, the usual complications associated with initiation by hydroperoxides apply (Section 3.3.2.5). [Pg.387]

Write the balanced chemical equation for (a) the thermal decomposition of potassium chlorate without a catalyst (b) the reaction of bromine with water (c) the reaction between sodium chloride and concentrated sulfuric acid, (d) Identify each reaction as a Bronsted acid—base, Lewis acid—base, or redox reaction. [Pg.772]

This is an typical example of a dicarboxylic acid in that C-C cleavage is the only route for oxidation. No study of the Co(III) oxidation has been made although it is highly probable that reaction would proceed through an oxalate complex. The thermal decomposition of Co(Ox)3 has been shown to be a first-order process and probably involves an internal redox reaction, viz. [Pg.396]

By adjusting the reaction pH, one can achieve a thermal-dynamical ly favorable redox reaction and produce reactive Cr olates in the dimeric or linear polymer forms for crosslinking. [Pg.146]

It explodes at temperatures around 150°C. Thermal decomposition appears to involve an internal redox reaction in the anion leading to formation of trichloro(chlorato)oxostannate(IV). [Pg.851]

In the production of formic acid, a slimy of calcium formate in 50% aqueous formic acid containing urea is acidified with strong nitric acid to convert the calcium salt to free acid, and interaction of formic acid (reducant) with nitric acid (oxidant) is inhibited by the urea. When only 10% of the required amount of urea had been added (unwittingly, because of a blocked hopper), addition of the nitric acid caused a thermal runaway (redox) reaction to occur which burst the (vented) vessel. A small-scale repeat indicated that a pressure of 150-200 bar may have been attained. A mathematical model was developed which closely matched experimental data. [Pg.1584]

Some of the investigations carried out in the first half of the twentieth century were related to CL associated with thermal decomposition of aromatic cyclic peroxides [75, 76] and the extremely low-level ultraviolet emission produced in different reaction systems such as neutralization and redox reactions involving oxidants (permanganate, halogens, and chromic acid in combination with oxalates, glucose, or bisulfite) [77], In this period some papers appeared in which the bright luminescence emitted when alkali metals were exposed to oxygen was reported. The phenomenon was described for derivatives of zinc [78], boron [79], and sodium, potassium, and aluminum [80]. [Pg.16]

Decomposition reactions are reactions in which a compound breaks down into two or more simpler substances. Although not all decomposition reactions are redox reactions, many are. For example, the thermal decomposition reactions, such as the common laboratory experiment of generating oxygen by heating potassium chlorate, are decomposition reactions ... [Pg.73]

Fig. 8-28. Cathodic polarization curves for several redox reactions of hydrated redox particles at an n-type semiconductor electrode of zinc oxide in aqueous solutions (1) = 1x10- MCe at pH 1.5 (2) = 1x10 M Ag(NH3) atpH12 (3) = 1x10- M Fe(CN)6 at pH 3.8 (4)= 1x10- M Mn04- at pH 4.5 IE = thermal emission of electrons as a function of the potential barrier E-Et, of the space charge layer. [From Memming, 1987.]... Fig. 8-28. Cathodic polarization curves for several redox reactions of hydrated redox particles at an n-type semiconductor electrode of zinc oxide in aqueous solutions (1) = 1x10- MCe at pH 1.5 (2) = 1x10 M Ag(NH3) atpH12 (3) = 1x10- M Fe(CN)6 at pH 3.8 (4)= 1x10- M Mn04- at pH 4.5 IE = thermal emission of electrons as a function of the potential barrier E-Et, of the space charge layer. [From Memming, 1987.]...
Example IV The Thermal and Oxidative Isomerization of Tetraalkyl Substituted Tetrahedrane Clusters to Cyclobutadiene Derivatives. Other remarkable structural changes during redox reactions, i.e. charge redistributions enforced by the respective energy differences, are observed for cluster compounds (1). On... [Pg.153]

A wide variety of peroxides have been used to produce alkyl radicals, either directly as fragments of the decomposition of peroxides, or indirectly by hydrogen abstraction from suitable solvents. The production of alkyl radicals used in homolytic alkylation has been accomplished by thermal or photochemical homolysis and recently also by redox reactions due to the possibilities offered by alkylation in acidic aqueous solution. [Pg.125]

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See also in sourсe #XX -- [ Pg.107 ]



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