Oxidation-reduction reactions outer sphere mechanism

Similarly, inner-sphere and outer-sphere mechanisms can be postulated for the reductive dissolution of metal oxide surface sites, as shown in Figure 2. Precursor complex formation, electron transfer, and breakdown of the successor complex can still be distinguished. The surface chemical reaction is unique, however, in that participating metal centers are bound within an oxide/hydroxide... 

The Electron Transfer Step. Inner-sphere and outer-sphere mechanisms of reductive dissolution are, in practice, difficult to distinguish. Rates of ligand substitution at tervalent and tetravalent metal oxide surface sites, which could be used to estimate upward limits on rates of inner-sphere reaction, are not known to any level of certainty. 

This chapter mainly focuses on the reactivity of 02 and its partially reduced forms. Over the past 5 years, oxygen isotope fractionation has been applied to a number of mechanistic problems. The experimental and computational methods developed to examine the relevant oxidation/reduction reactions are initially discussed. The use of oxygen equilibrium isotope effects as structural probes of transition metal 02 adducts will then be presented followed by a discussion of density function theory (DFT) calculations, which have been vital to their interpretation. Following this, studies of kinetic isotope effects upon defined outer-sphere and inner-sphere reactions will be described in the context of an electron transfer theory framework. The final sections will concentrate on implications for the reaction mechanisms of metalloenzymes that react with 02, 02 -, and H202 in order to illustrate the generality of the competitive isotope fractionation method. 

It has been shown that the oxidation-reduction reactions of transition metal complexes can occur through two different mechanisms (i) inner-sphere mechanism, when the two reactants share one or more ligands of their first coordination spheres in the activated complex and (ii) outer-sphere mechanism, when the first coordination spheres of the two reactants are left intact (as far as the number and kind of ligands present are concerned) in the activated complex. As mentioned before, the inner-sphere reactions cannot be faster than ligand substitution and... 

In recent years, there has been a great deal of interest in the mechanisms of electron transfer processes.52-60 It is now recognized that oxidation-reduction reactions involving metal ions and their complexes are mainly of two types inner-sphere (ligand transfer) and outer-sphere (electron transfer) reactions. Prototypes of these two processes are represented by the following reactions. 

An outer sphere oxidation of free CN1 by TPPFeIII(CN)21", which is mechanistically described by Reaction 13. The electrochemical oxidation of cyanide ion in acetonitrile occurs at potentials more positive than +0.5 volt vs. SCE (22). The electrochemical reduction of TPP-FeIII(CN)21" in acetonitrile occurs at a potential of —0.5 volt vs. SCE (25). Thus an outer sphere mechanism is considered unlikely. 

Cyano metal complexes undergo a variety of oxidation-reduction reactions. One of the most studied is the fast self-exchange reaction of the [Fe(CN)4] /" anions information from this research was instrumental in establishing the outer-sphere mechanism (see Outer-sphere Reaction) for transition metal oxidation-reduction reactions (see Electrochemistry Applications in Inorganic Chemistry). The nature... 

Oxidases couple the oxidation of an organic substrate to the two- or four-electron reduction of O2, producing H2O2 or two molecules of H2O, respectively. Oxygen atoms from dioxygen are not incorporated into the product, unlike reactions catalyzed by oxygenases. Oxidase reactions may proceed via iimer-sphere or outer-sphere mechanisms. 

The reactivity of the Cu/3 complex was studied kinetically " in the two electron-transfer reactions shown below. Cu(II) ion was reduced with ascorbic acid through an inner-sphere process in which ascorbic acid coordinates to the Cu complex and then transfers an electron to the Cu(II) ion. Cu(II) ion was also reduced with Fe(II)(phenanthroline)3 via an outer-sphere mechanism in which electron-transfer occurs when a reductant and an oxidant move into sufficient proximity. 

Marcus LFER. Oxidation-reduction reactions involving metal ions occur by (wo types of mechanisms inner- and outer-sphere electron transfer. In the former, the oxidant and reductant approach intimately and share a common primary hydration sphere so that the activated complex has a bridging ligand between the two metal ions (M—L—M ). Inner-sphere redox reactions thus involve bond forming and breaking processes like other group transfer and substitution rcaclions, and transition-state theory applies directly to them. In outer-sphere electron transfer, the primary hydration spheres remain intact. The... 

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