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Electron transfer-oxygenation mechanism

SCHEME 14.7 Anthracene oxidation via electron transfer-oxygenation mechanism (Elaborated from Ref. [38]). [Pg.372]

This quinone reacts in aqueous solution with OH and H adducts of cytosines and uracils by an electron transfer/addition mechanism, similar to Eq. 18 [28], Addition takes place at the quinone carbonyl oxygen to produce an anthroxyl radical. This then undergoes spontaneous C-O heterolysis ... [Pg.136]

FIGURE 10.29 Typical photoproducts observed (A) in the irradiation (A = 300 nm) in air of naphthalene and 1-methylnaphthalene adsorbed on silica and formed by a Type I electron transfer (superoxide) mechanism (Barbas et al., 1993) and (B) in the irradiation in air of acenaphthylene (A = 350 nm) adsorbed on silica formed by a Type II singlet oxygen mechanism (Barbas et al., 1994) (adapted from Dabestani, 1997). [Pg.514]

Protons are relatively simple targets for sensor molecules and do not require engineered receptors, however, achievement of selective interactions with other chemical species requires much more elaborate receptors. In the most cases cations are bound via electrostatic or coordinative interactions within the receptors alkali metal cations, which are rather poor central ions and form only very weak coordination bonds, are usually bound within crown ethers, azacrown macrocycles, cryptands, podands, and related types of receptor moieties with oxygen and nitrogen donor atoms [8], Most of the common cation sensors are based on the photoinduced electron transfer (PET) mechanism, so the receptor moiety must have its redox potential (HOMO energy) adjusted to quench luminescence of the fluorophore (Figure 16.3). [Pg.261]

Step 1 Hydrogen peroxide is generated in the fuel cell. The dominant peroxide generation mechanism has not been definitively established, but may be generated electrochemically from the two electron transfer oxygen reduction reaction... [Pg.152]

Archakov, 1975). In the active center of the enzyme an ion Fe in a low-spin state is present. The first step of the hydroxylation reaction is the reduction of the iron ion in the active center of the enzyme (Griffin et al, 1975). The use of spin-labeled analogues of substrates made it possible to observe the electron transfer from the reduced iron ion to the radical under anaerobic conditions. On the basis of studies of the electron transfer kinetics in these systems a conclusion was drawn concerning the possible mechanism of action of the enzyme, in which by a direct electron transfer oxygen can be activated (for example, to O2 of the radical (Griffin et aL, 1975), and the substrate oxidized as well. [Pg.225]

The mechanism of chemiluminescence is still being studied and most mechanistic interpretations should be regarded as tentative. Nevertheless, most chemiluminescent reactions can be classified into (/) peroxide decomposition, including biolurninescence and peroxyoxalate chemiluminescence (2) singlet oxygen chemiluminescence and (J) ion radical or electron-transfer chemiluminescence, which includes electrochemiluminescence. [Pg.262]

This oxidation of DMSO is catalyzed by Ag+ cations. Kinetic and infrared spec-trometric evidence fits a mechanism where DMSO coordinates rapidly with Ag+ through its oxygen atom. The oxidation of this complex by Ce4 + then constitutes the slow step. The Ag2+ adduct would then undergo an intramolecular electron transfer in a fast step resulting in the oxidation of DMSO. [Pg.1062]

The reason for the exponential increase in the electron transfer rate with increasing electrode potential at the ZnO/electrolyte interface must be further explored. A possible explanation is provided in a recent study on water photoelectrolysis which describes the mechanism of water oxidation to molecular oxygen as one of strong molecular interaction with nonisoenergetic electron transfer subject to irreversible thermodynamics.48 Under such conditions, the rate of electron transfer will depend on the thermodynamic force in the semiconductor/electrolyte interface to... [Pg.512]

Several mechanisms have been proposed to explain the activation of carbon surfaces. These have Included the removal of surface contaminants that hinder electron transfer, an Increase In surface area due to ralcro-roughenlng or bulld-up of a thin porous layer, and an Increase In the concentrations of surface functional groups that mediate electron transfer. Electrode deactivation has been correlated with an unintentional Introduction of surface contaminants (15). Improved electrode responses have been observed to follow treatments which Increase the concentration of carbon-oxygen functional groups on the surface (7-8,16). In some cases, the latter were correlated with the presence of electrochemical surface waves (16-17). However, none of the above reports discuss other possible mechanisms of activation which could be responsible for the effects observed. [Pg.583]

This oxidative process has been successful with ketones,244 esters,245 and lactones.246 Hydrogen peroxide can also be used as the oxidant, in which case the alcohol is formed directly.247 The mechanisms for the oxidation of enolates by oxygen is a radical chain autoxidation in which the propagation step involves electron transfer from the carbanion to a hydroperoxy radical.248... [Pg.1140]

Fig. 1 Schematic mechanism for the long-distance oxidation of DNA. Irradiation of the anthraquinone (AQ) and intersystem crossing (ISC) forms the triplet excited state (AQ 3), which is the species that accepts an electron from a DNA base (B) and leads to products. Electron transfer to the singlet excited state of the anthraquinone (AQ 1) leads only to back electron transfer. The anthraquinone radical anion (AQ ) formed in the electron transfer reaction is consumed by reaction with oxygen, which is reduced to superoxide. This process leaves a base radical cation (B+-, a hole ) in the DNA with no partner for annihilation, which provides time for it to hop through the DNA until it is trapped by water (usually at a GG step) to form a product, 7,8-dihydro-8-oxoguanine (8-OxoG)... Fig. 1 Schematic mechanism for the long-distance oxidation of DNA. Irradiation of the anthraquinone (AQ) and intersystem crossing (ISC) forms the triplet excited state (AQ 3), which is the species that accepts an electron from a DNA base (B) and leads to products. Electron transfer to the singlet excited state of the anthraquinone (AQ 1) leads only to back electron transfer. The anthraquinone radical anion (AQ ) formed in the electron transfer reaction is consumed by reaction with oxygen, which is reduced to superoxide. This process leaves a base radical cation (B+-, a hole ) in the DNA with no partner for annihilation, which provides time for it to hop through the DNA until it is trapped by water (usually at a GG step) to form a product, 7,8-dihydro-8-oxoguanine (8-OxoG)...
Thiocarbamate (tc, RHNCSO-) is a monodentate ambidentate ligand, and both oxygen- and sulfur-bonded forms are known for the simple pentaamminecobalt(III) complexes. These undergo redox reactions with chromium(II) ion in water via attack at the remote O or S atom of the S- and O-bound isomers respectively, with a structural trans effect suggested to direct the facile electron transfer in the former.1045 A cobalt-promoted synthesis utilizing the residual nucleophilicity of the coordinated hydroxide in [Co(NH3)5(OH)]2+ in reaction with MeNCS in (MeO)3PO solvent leads to the O-bonded monothiocarbamate, which isomerizes by an intramolecular mechanism to the S-bound isomer in water.1046... [Pg.93]


See other pages where Electron transfer-oxygenation mechanism is mentioned: [Pg.735]    [Pg.40]    [Pg.151]    [Pg.113]    [Pg.125]    [Pg.386]    [Pg.79]    [Pg.655]    [Pg.129]    [Pg.338]    [Pg.102]    [Pg.303]    [Pg.195]    [Pg.2723]    [Pg.2728]    [Pg.728]    [Pg.353]    [Pg.373]    [Pg.382]    [Pg.105]    [Pg.256]    [Pg.114]    [Pg.1062]    [Pg.172]    [Pg.1506]    [Pg.388]    [Pg.172]    [Pg.428]    [Pg.103]    [Pg.408]    [Pg.1062]    [Pg.155]    [Pg.156]    [Pg.227]    [Pg.36]   
See also in sourсe #XX -- [ Pg.372 ]




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Electron transfer mechanisms

Electron transferring mechanism

Oxygen mechanism

Oxygen transfer mechanism

Oxygen transferate

Oxygenate mechanism

Oxygenates mechanism

Oxygenation mechanism

Transfer mechanism

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