Electron transfer. 154. Reaction of the nitrosodisulfonate anion radical with one- and multi-electron inorganic reductants

The nitrosodisulfonate anion radical, NO(SO₃)₂ ^2-, a single electron oxidant, reacts cleanly with an array of metal-center reductants. Rates for substitution-labile species generally fall in the range 10⁴ -10⁵ M^-1 s^-1, both for le^-[Eu^II, Fe^II(EDTA)] and 2e^-(U^IV, In^I, Ge^II and Sn^II) reagents. The more weakly reducing donor VO²⁺ reacts more slowly (3 M^-1 s^-1 at 22°C) and the substitution-inert complex Fe(CN)₆ ^4- still more sluggishly. Reductions with the non-metal related donors, azide, formate, hypophosphite, hyponitrite and H2₂AsO₃ ^-, fall in the range 10^-4 -10^-2 M^-1 s^-1. Reactions yield the product HON(SO₃)₂ ^2-. Kinetic decay curves feature no irregularities reflecting formation or loss of one or more transients on a time scale comparable to that of the main conversion, indicating that the experimental rates pertaining to the 2e reductants and to hydrazine (a 4e reductant) are determined by the initial le transfer and that follow-up steps are rapid. The usual distinction between complementary and noncomplementary redox reactions applies poorly to reductions of NO(SO₃)₂ ^2-. Rapid reductions require (1) an adequate potential difference, (2) the possibility of an inner-sphere path and (3) the availability of one or more nonbonding electrons at the reducing site. Substitution-labile metal-based reducing centers embracing a wide range of formal potentials, both le^- and 2e^- donors, may react speedily, although the latter group must operate in steps.     

Outer-sphere oxidation of the superoxide radical anion

Efforts to use the Marcus model to describe oxidations of the superoxide radical anion (O(2-)) by transition-metal complexes have failed dramatically, with discrepancies between theory and experiment spanning 13 orders of magnitude. As a result, the prevailing view is that these reactions involve some complex interactions that are not yet understood. We now show that once the familiar form of the Marcus cross relation (MCR) is modified to allow for the relatively small size of O(2-), excellent agreement is obtained between theory and experiment. This simple finding dispels the decades of uncertainty surrounding these reactions and provides a reliable method for determining whether oxidations of (O2)- occur via inner- or outer-sphere pathways. More generally, the modified MCR is applicable to any homogeneous electron-transfer process characterized by significant differences in size between electron donors and acceptors.     

Kinetics of the reaction of the sulfate radical with the oxalate anion

The kinetics of the reaction of the sulfate radical, SO₄⁻, with the oxalate anion C₂O₄²⁻ was studied in aqueous solution and second-order rate constants, corrected for the effects of ionic strength, derived. Measurements were carried out over the temperature range 24–60°C resulting in the expression k₀ = 2.10 ± 0.96 × 10⁸ exp(−1080 ± 140/T) L mol⁻¹ s⁻¹. © 1996 John Wiley & Sons, Inc.     

Kinetics of one-electron oxidation by the ClO radical

Pulse radiolysis studies were carried out to determine the rate constants for reactions of ClO radicals in aqueous solution. These radicals were produced by the reaction of OH with hypochlorite ions in N₂O saturated solutions. The rate constants for their reactions with several compounds were determined by following the build up of the product radical absorption and in several cases by competition kinetics. ClO was found to be a powerful oxidant which reacts very rapidly with phenoxide ions to form phenoxyl radicals and with dimethoxybenzenes to form the cation radicals (k = 7 × 10⁸ −2 × 10⁹ M^-1 s^-1). ClO also oxidizes ClO^-₂ and N^-₃ ions rapidly (9.4 × 10⁸ and 2.5 × 10⁸ M^-1 s^-1, respectively), but its reactions with formate and benzoate ions were too slow to measure. ClO does not oxidize carbonate but the CO^-₃ radical reacts with ClO^- slowly (k = 5.1 × 10⁵ M^-1 s^-1).     

Kinetics of chalcone oxidation by peroxide anion catalysed by poly-l-leucine

An insight into the kinetics, mechanism and optimum reaction conditions of the Julia-Colonna epoxidation has been gained using a soluble polyleucine catalyst.     

Reactivity of superoxide anion radical with a perchlorotriphenylmethyl (trityl) radical

The reaction of superoxide radical with a tricarboxylate derivative of perchlorotriphenylmethyl radical (PTM-TC) is studied. PTM-TC is a stable ("inert") free radical, which gives a single sharp electron paramagnetic resonance (EPR) peak in aqueous solutions. PTM-TC also gives a characteristic optical absorption at 380 nm. Superoxide, on reaction with PTM-TC, induced a decrease in the intensity of the EPR signal and optical absorption of PTM-TC at 380 nm. The signal loss was specific to superoxide and linearly dependent on the superoxide flux in the system. Competitive kinetics experiments revealed that PTM-TC reacts with superoxide with an apparent second-order rate constant of 8.3x10(8) M(-1) s(-1). Electrochemical and mass spectrometric analyses of the reaction suggested the formation of perchlorotriphenylmethane and molecular oxygen as products. The high sensitivity of detection of PTM-TC combined with the high rate constant of the reaction of superoxide with PTM-TC may offer a potential opportunity for measurement of superoxide in biological systems. In conclusion, the PTM-TC molecule has high sensitivity and specificity for superoxide radicals and thus may enable quantitative detection of superoxide generation in biological systems using EPR and/or spectrophotometric methods.     

Kinetics of protonation of the 1,2-dinitrobenzene radical anion and dianion by phenol

The kinetics of protonation of electrochemically generated 1,2-dinitrobenzene (1,2-DNB) radical anions and dianions by phenol in DMF was studied by chronoamperometry. In the presence of phenol, the rate-determining step of electroreduction at the first wave potentials is the protonation of the 1,2-DNB radical anion with a rate constant of 103±13 L mol^s-1 s^s-1. The number of electrons involved in the process with phenol excess is 3, which corresponds to the formation of azoxy compounds. At the second wave potentials under these conditions, the electroreduction process is four-electron, which corresponds to the formation of 2-nitrophenyl-hydroxylamine, The rate constant for 1,2-DNB dianion protonation is 265±60 Lmol^s-1 s^s-1. The comparison of the experimental data with the results of quantum chemical calculation suggests the orbital control of the protonation reaction.     

Kinetics of the initial stage of catalytic radical chain oxidation of cumene with catalyst deactivation

We have developed a method for estimating the rate constant for the reaction of catalyst deactivation in a radical chain process in the presence of catalysts with low stability. Its applicability is demonstrated in the reaction of oxidation of cumene in the presence of alkylammonium halides.Translated from Teoreticheskaya i Éksperimental'naya Khimiya, Vol. 30, No. 2, pp. 69–74, March–April, 1994.     

Kinetics and mechanism of protection of thymine from sulphate radical anion under anoxic conditions

The rates of photooxidation of thymine in presence of peroxydisulphate (PDS) have been determined by measuring the absorbance of thymine at 264 nm spectrophotometrically. The rates and the quantum yields (φ) of oxidation of thymine by sulphate radical anion have been determined in the presence of different concentrations of caffeic acid. Increase in [caffeic acid] is found to decrease the rate of oxidation of thymine suggesting that caffeic acid acts as an efficient scavenger of SO ₄ ^•- and protects thymine from it. Sulphate radical anion competes for thymine as well as for caffeic acid. The rate constant of sulphate radical anion with caffeic acid has been calculated to be 1.24 x 10¹⁰ dm³ mol^-1s^-1. The quantum yields of photooxidation of thymine have been calculated from the rates of oxidation of thymine and the light intensity absorbed by PDS at 254 nm, the wavelength at which PDS is activated to sulphate radical anion. From the results of experimentally determined quantum yields (φ_expt1) and the quantum yields calculated (φ_cl) assuming caffeic acid acting only as a scavenger of SO ₄ ^•- radicals show that φ_expt1 values are lower than φ_cl values. The φ ’ values, which are experimentally found quantum yield values at each caffeic acid concentration and corrected for SO ₄ ^•- scavenging by caffeic acid, are also found to be greater than φ_expt1 values. These observations suggest that the thymine radicals are repaired by caffeic acid in addition to scavenging of sulphate radical anions.     

Mechanisms of oxidation of guanine in DNA by carbonate radical anion, a decomposition product of nitrosoperoxycarbonate

Peroxynitrite is produced during inflammation and combines rapidly with carbon dioxide to yield the unstable nitrosoperoxycarbonate, which decomposes (in part) to CO(3) (.-) and (.)NO(2) radicals. The CO(3) (.-) radicals oxidize guanine bases in DNA through a one-electron transfer reaction process that ultimately results in the formation of stable guanine oxidation products. Here we have explored these mechanisms, starting with a spectroscopic study of the kinetics of electron transfer from 20-22mer double-stranded oligonucleotides to CO(3) (.-) radicals, together with the effects of base sequence on the formation of the end-products in runs of one, two, or three contiguous guanines. The distributions of these alkali-labile lesions were determined by gel electrophoresis methods. The cascade of events was initiated through the use of 308 nm XeCl excimer laser pulses to generate CO(3) (.-) radicals by an established method based on the photodissociation of persulfate to sulfate radicals and the oxidation of bicarbonate. Although the Saito model (Saito et al., J. Am. Chem. Soc. 1995, 117, 6406-6407) predicts relative ease of one-electron oxidations in DNA, following the trend 5'-GGG > 5'-GG > 5'-G, we found that the rate constants for CO(3) (.-)-mediated oxidation of guanines in these sequence contexts (k(5)) showed only small variation within a narrow range [(1.5-3.0)x10(7) M(-1) s(-1)]. In contrast, the distributions of the end-products are dependent on the base sequence context and are higher at the 5'-G in 5'-GG sequences and at the first two 5'-guanines in the 5'-GGG sequences. These effects are attributed to a combination of initial hole distributions among the contiguous guanines and the subsequent differences in chemical reaction yields at each guanine. The lack of dependence of k(5) on sequence context indicates that the one-electron oxidation of guanine in DNA by CO(3) (.-) radicals occurs by an inner-sphere mechanism.     

Kinetics and mechanism of protection of thymine from phosphate radical anion under anoxic conditions

The rates of photooxidation of thymine in the presence of peroxydiphosphate (PDP) have been determined by measuring the absorbance of thymine at 264 nm spectrophotometrically. The rates and the quantum yields (φ) of oxidation of thymine by phosphate radical anion have been determined in the presence of different concentrations of dithiothreitol (DTT). An increase in DTT is found to decrease the rate of oxidation of thymine, suggesting that DTT acts as an efficient scavenger of PO₄^·2? and protects thymine from it. Phosphate radical anion competes for thymine as well as DTT; the rate constant for the phosphate radical anion with DTT has been calculated to be 2.21 × 10⁹ dm³ mol^?1 s^?1, assuming the rate constant of phosphate radical anion reaction with thymine as 9.6 × 10⁷ dm³ mol^?1 s^?1. The quantum yields of photooxidation of thymine have been calculated from the rates of oxidation of thymine and the light intensity absorbed by PDP at 254 nm, the wavelength at which PDP is activated to phosphate radical anion. From the results of experimentally determined quantum yields (φ_exptl) and the quantum yields calculated (φ_cl), assuming DTT acts only as a scavenger of PO₄^·2? radicals, show that φ_exptl values are lower than φ_cl values. The φ′ values, which are experimentally found quantum yield values at each DTT concentration and corrected for PO₄^·2? scavenging by DTT, are also found to be greater than φ_exptl values. These observations suggest that the thymine radicals are repaired by DTT in addition to scavenging of phosphate radical anions. © 2001 John Wiley & Sons, Inc. Int J Chem Kinet 33: 271–275, 2001     

Kinetics of polymeric radical oxidation with molecular oxygen in poly(methyl methacrylate) films

In poly(methyl methacrylate) films, the kinetics of the oxidation of polymeric radicals and azobenzenenitrenes with molecular oxygen dissolved in the polymer is studied. The free radicals are produced at 77 K by irradiating the polymer with UV light, fast electrons, or γ rays. The concentration of oxygen is varied from 4.5 × 10¹⁸ to 3.1 × 10¹⁹ cm^?3; the temperature of the reaction, from 90 to 130 K. The reaction is carried out in excess oxygen. The kinetics of radical oxidation is shown to be independent of the type of radiation that stimulates the formation of radicals and coincides with the kinetics of the oxidation of azobenzenenitrenes, which are uniformly dissolved in the polymer. It is concluded that the structure of the polymer in the vicinity of the radicals is virtually the same as the structure of the polymer bulk. The activation energy of the oxygen diffusion coefficient calculated according to the radical oxidation kinetics amounts to ～30 kJ/mol.     

Dibromine radical anion reactions with heme enzymes

Reactions of Br ₂ ^– radical anion with heme enzymes, catalase and horseradish peroxidase, have been studied by pulse radiolysis. It has been found that Br ₂ ^– does not react with the heme centre of investigated enzymes. Dibromine radical anion reacts with tryptophan residues of catalase without any influence on the activity of catalase. It is suggested that in pulse radiolysis studies, where horseradish peroxidase is at about tenfold excess towards Br ₂ ^– , the enzyme is modified rather by Br₂, than by Br ₂ ^– .     

Competitive coupling of amide anion over menthyl propionate anion with aryl radical

A competitive coupling of amide anion over menthyl propionate anion with aryl radicalin photo-S_(RN) 1 mechanism was encountered. The rcaction afforded N-aryl propionic amide in excel-lent yield. In contrast, the expected nucleophilic photo-S_(RN) 1 substitution originating from the carb-anion was observed in the case of t-butyl propionate. According to the proposed mechanisms and MOcorrelation diagrams of the coupling step of nucleophiles with aryl radical, the interesting con-trast is reasonably attributed to the variation in energy gap between π~*c-o and π~*Ar of (ArNu)-Usually, the odd electron of (ArNu)- is weightly populated at π~*c-o, however, the diminished priv-ilege of π~*c-o in menthyl propionate promotes a dominant population of the odd electron at π~*Ar,which leads to the fragmentation of (ArNu)- into the starting carbanion and aryl radical.     

Reactions of heme proteins with carbonate radical anion

Reactions of radiolytically generated CO₃ ^•− with some ferric heme proteins, catalase, cytochrome c, and horseradish peroxidase (HRP), were studied. Carbonate radical anion oxidized amino acid residues of these proteins, but did not react directly with heme iron. HRP and catalase lost about 30% and 20% of their activity, respectively, after the reaction with 100 μM of CO₃ ^•−. The rate constants of the reactions of CO₃ ^•− with the investigated proteins measured by the pulse radiolysis method at pH 8–8.4 and 10 varied from 1.0 × 10⁸ M⁻¹ s⁻¹ (for cytochrome c) to 3.7 × 10⁹ M⁻¹ s⁻¹ (for catalase).     

Kinetics of OH radical reactions with a series of ethers

The rate constants for the reactions of OH with dimethyl ether (k₁), diethyl ether (k₂), di-n-propyl ether (k₃), di-isopropyl ether (k₄), and di-n-butyl ether (k₅) have been measured over the temperature range 230–372 K using the pulsed laser photolysis-laser induced fluorescence (PLP-LIF) technique. The temperature dependence of k₁,k₄, can be expressed in the Arrhenius plots form: k₁ = (6.30 ± 0.10) × 10^?12 exp[?(234 ± 34)/T] and k₄ = (4.13 ± 0.10) × 10^?12 exp[(274 ± 26)/T]. The Arrhenius plots for k₂,k₃, and k₅, were curved and they were fitted to the three parameter expressions: k₂ = (1.02 ± 0.08) × 10^?17 T² exp[(797 ± 24)/T], k₃ = (1.84 ± 0.23) × 10^?17T² exp[(767 ± 34)/T], and k₅ = (6.29 ± 0.74) × 10^?18T² exp[(1164 ± 34)/T]. The values at 298 K are (2.82 ± 0.21) × 10^?12, (1.36 ± 0.11) × 10^?11,(2.17 ± 0.16) × 10^?11, (1.02 ± 0.10) × 10^?11, and (2.69 ± 0.22) × 10^?11 for k₁, k₂, k₃, k₄, and k₅, respectively, (in cm³ molecule^?1 s^?1). These results are compared to the literature data. © 1995 John Wiley & Sons, Inc.     

Intrinsic anion oxidation potentials

Anions of lithium battery salts have been investigated by electronic structure calculations with the objective to find a computational measure to correlate with the observed (in)stability of nonaqueous lithium battery electrolytes vs oxidation often encountered in practice. Accurate prediction of intrinsic anion oxidation potentials is here made possible by computing the vertical free energy difference between anion and neutral radical (Delta Gv) and further strengthened by an empirical correction using only the anion volume as a parameter. The 6-311+G(2df,p) basis set, the VSXC functional, and the C-PCM SCRF algorithm were used. The Delta Gv calculations can be performed using any standard computational chemistry software.     

Kinetics of oxidation of carbonyl compounds by peroxomonosulfate. Formaldehyde, formic acid and formate anion

Kinetics of oxidation of formaldehyde, formic acid and formate anion by peroxomonosulfate (PMS) were studied. Formaldehyde is oxidized both by HSO ₅ ^– and SO ₅ ^2– , whereas formic acid and formate ion are oxidized by SO ₅ ^2– alone. The kinetic results show that the formaldehyde is 10³ times more reactive than formic acid, which in turn reacts 10² times faster than formate anion. Mechanisms are discussed in terms of the kinetic results.

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, . HSO ₅ ^– , SO ₅ ^2– , SO ₅ ^2– . , . 10³ , , , , . 10² , . .