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Kinetics of atmospheric oxidation of nitrous acid by oxygen in aqueous medium
AbstractThe facts that the high concentrations of nitrous acid have been reported in dew, fog, rain and cloud water and that its oxidation by dissolved oxygen is very fast in freezing conditions have led us to study the kinetics of aqueous phase oxidation of nitrous acid by dissolved oxygen in the pH range 1.0–4.5 at 30°C. The reaction was followed by measuring [O2] and under pseudo-first-order conditions the results were in agreement with the rate law:where k0 is third-order composite rate coefficient and Ka is the dissociation constant of HNO2. The values of k0 and Ka were determined to be 1×102L2mol−2s−1 and 3.84×10−4, respectively.Consistent with the kinetics results two alternative mechanisms have been considered. The first of these mechanisms assumes an intermediate complex formation, [HNO2.O2], by the reaction of HNO2 and O2 in a rapid pre-equilibrium, followed by the reaction of this intermediate with another molecule of HNO2. The second mechanism, originally proposed by Damschen and Martin [1983. Aqueous aerosol oxidation of nitrous acid by O2, O3 and H2O2. Atmospheric Environment 17, 2005–2011], assumes the formation of a dimer, [HNO2]2, in a rapid pre-equilibrium followed by the reaction of the dimer with O2 to form HNO3. The application of the mechanisms to fast oxidation of nitrite by dissolved oxygen under freezing conditions is discussed.
Kinetics of atmospheric oxidation of nitrous acid by oxygen in aqueous medium
AbstractThe facts that the high concentrations of nitrous acid have been reported in dew, fog, rain and cloud water and that its oxidation by dissolved oxygen is very fast in freezing conditions have led us to study the kinetics of aqueous phase oxidation of nitrous acid by dissolved oxygen in the pH range 1.0–4.5 at 30°C. The reaction was followed by measuring [O2] and under pseudo-first-order conditions the results were in agreement with the rate law:where k0 is third-order composite rate coefficient and Ka is the dissociation constant of HNO2. The values of k0 and Ka were determined to be 1×102L2mol−2s−1 and 3.84×10−4, respectively.Consistent with the kinetics results two alternative mechanisms have been considered. The first of these mechanisms assumes an intermediate complex formation, [HNO2.O2], by the reaction of HNO2 and O2 in a rapid pre-equilibrium, followed by the reaction of this intermediate with another molecule of HNO2. The second mechanism, originally proposed by Damschen and Martin [1983. Aqueous aerosol oxidation of nitrous acid by O2, O3 and H2O2. Atmospheric Environment 17, 2005–2011], assumes the formation of a dimer, [HNO2]2, in a rapid pre-equilibrium followed by the reaction of the dimer with O2 to form HNO3. The application of the mechanisms to fast oxidation of nitrite by dissolved oxygen under freezing conditions is discussed.
Kinetics of atmospheric oxidation of nitrous acid by oxygen in aqueous medium
Mudgal, Punit K. (author) / Bansal, S.P. (author) / Gupta, K.S. (author)
Atmospheric Environment ; 41 ; 4097-4105
2007-01-09
9 pages
Article (Journal)
Electronic Resource
English
Nitrite , Nitrous acid , Nitric acid , Oxygen , Oxidation , Kinetics , Autoxidation
Observation of atmospheric nitrous acid with DOAS in Beijing, China
| Online Contents | 2006
Aqueous aerosol oxidation of nitrous acid by O2, O3 AND H2O2
| Elsevier | 1983