The application of ozone along with hydrogen peroxide,
commonly
referred to as peroxone oxidation, is a widely investigated technique
for wastewater treatment. Degradation of ozone in water is a key step
in the pollutant degradation mechanism, particularly in peroxone oxidation.
However, the degradation of ozone in water is not understood at a
low pH (<6). This study reveals that current ozone degradation
models overestimate degradation at a low pH because the rate constants
involved in the dissociation equilibrium of the hydroperoxyl radical
are inaccurate. Here, the rate constants of forward and backward reactions
were calculated with ab initio quantum chemical calculations
computed from the CCSD (T) theory to be 1.45 × 103 s–1 and 8.6 × 107 m3 kmol –1 s–1, respectively. After
modifying the current kinetic model by using the calculated rate constants,
the predictions of ozone half-lives at a low pH (<6) are improved
by 1–2 orders of magnitude in pure water (without organic matter
and carbonate species) in comparison with the available experimental
results. The ozone decomposition kinetic model was used to develop
a comprehensive kinetic model for peroxone oxidation of toluene. The
results demonstrate that the new rate constants considerably improve
the peroxone oxidation process as well.
An ab initio study, using the coupled cluster calculations (CCSD) method was conducted to investigate the kinetics of the ozone degradation in gas and aqueous phases considering the reaction of ozone with the hydroperoxyl radical. Two potential transition state paths, oxygen and hydrogen transfer, are studied and compared. It was revealed by the ab initio quantum chemical calculations that the calculated overall rate constant in the gas phase differs by approximately an order of magnitude from measured values. However, the calculated selectivity (branching fraction), which was measured directly with isotope studies of hydrogen atom transfer, is almost exactly equal to the experimental value at 298.15 K. The sensitivity analysis showed that adding the reaction between ozone and hydroperoxyl radical to the kinetic model accelerates the decomposition process by more than four times in the aqueous phase (pH = 7–8.5), and for an order of magnitude change in the rate constant of this reaction, the decomposition half‐life changes by 20–45 %. This result might affect our understanding of atmospheric ozone chemistry.
An ab initio study was conducted to investigate the kinetics of the ozone degradation in gas and aqueous phases considering the reaction of ozone with hydroperoxyl radical using coupled cluster calculations (CCSD) method. Oxygen atom transfer and hydrogen atom transfer are studied and compared as two potential transition state paths. The ab initio quantum chemical calculations showed that the calculated overall rate constant in the gas phase differs by almost an order of magnitude from the measured values. However, the calculated selectivity (branching fraction) of hydrogen atom transfer is almost exactly the experimental value at room temperature, which was measured directly with isotope studies. This result may affect our understanding of atmospheric ozone chemistry.
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