1995
DOI: 10.1021/j100039a025
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Kinetic Modeling of the KMnO4/H2C2O4/H2SO4 Reaction: Origin of the bistability in a CSTR

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Cited by 16 publications
(44 citation statements)
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“…20 This autocatalytic role usually takes place when colloidal MnO 2 is one of the reaction products, as happens in the permanganate oxidation of the amino acid L-threonine in neutral phosphatebuffered solutions, 21 but it can also occur when the colloid is formed as an intermediate, as in the permanganate oxidation of formic acid in perchloric media. 22 Moreover, for the permanganate oxidation of oxalic acid in sulfuric solutions, arguably the most important and most studied of the permanganate reactions, 23 although its mechanism has proven so far to be rather elusive, 24,25 it has been recently reported that its autocatalysis cannot be explained if the Mn(II)-oxalate complex formed as reaction product is considered the only autocatalyst, and that an essential reaction pathway to explain its kinetic behavior takes place on the surface of the MnO 2 colloidal particles formed as a long-lived intermediate, hence providing a positive feedback loop for the reaction. 26 It thus seems a plausible hypothesis that soluble forms of colloidal MnO 2 might play the role of a heterogeneous autocatalyst in many permanganate reactions, not only when formed as a reaction product (in neutral solutions) but also when formed as a long-lived intermediate (in acidic solutions).…”
Section: Introductionmentioning
confidence: 99%
“…20 This autocatalytic role usually takes place when colloidal MnO 2 is one of the reaction products, as happens in the permanganate oxidation of the amino acid L-threonine in neutral phosphatebuffered solutions, 21 but it can also occur when the colloid is formed as an intermediate, as in the permanganate oxidation of formic acid in perchloric media. 22 Moreover, for the permanganate oxidation of oxalic acid in sulfuric solutions, arguably the most important and most studied of the permanganate reactions, 23 although its mechanism has proven so far to be rather elusive, 24,25 it has been recently reported that its autocatalysis cannot be explained if the Mn(II)-oxalate complex formed as reaction product is considered the only autocatalyst, and that an essential reaction pathway to explain its kinetic behavior takes place on the surface of the MnO 2 colloidal particles formed as a long-lived intermediate, hence providing a positive feedback loop for the reaction. 26 It thus seems a plausible hypothesis that soluble forms of colloidal MnO 2 might play the role of a heterogeneous autocatalyst in many permanganate reactions, not only when formed as a reaction product (in neutral solutions) but also when formed as a long-lived intermediate (in acidic solutions).…”
Section: Introductionmentioning
confidence: 99%
“…The aim of this phase was that all elementary reaction steps which can occur in a decomposition must be included at least in one generated decomposition. Some of these decompositions satisfied (6) with a positive integer n greater than 1, although the greatest common divisor of the components of the appropriate vector y was in all cases 1. The total number of possible decompositions is unknown and is with several magnitude higher than 294.…”
Section: Computation Of Reaction Mechanismsmentioning
confidence: 99%
“…Of the 673 elementary steps we have found 314, not taking part in any of the decompositions, and they cannot even take part in any decomposition. If we prescribe the presence of any of them in a decomposition then (6) will have no solution.…”
Section: Computation Of Reaction Mechanismsmentioning
confidence: 99%
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