A study of the reaction O−3+CO2?CO−3+O2 and its implication on the thermochemistry of CO3 and O3 and their negative ions

Abstract

The reaction O⁻₃+CO₂?CO⁻₃+O₂ has been examined in the forward and reverse directions in a variable‐temperature flowing afterglow from 200 to 600 K and in a flow‐drift tube at mean relative kinetic energies from 0.04 to 1 eV. The forward direction is clearly established as the exothermic direction. Furthermore, collisional dissociation of CO⁻₃ and O⁻₃ ions in the flow‐drift tube at high E/N to form O⁻ shows that CO⁻₃ is the more stable ion. All of this implies that D (CO₂+O⁻) ≳D (O₂+O⁻). Kinetic‐equilibrium studies at the higher temperatures show that the reverse rate constant is less than 6×10⁻¹⁵ cm³ s⁻¹ below 600 K. When this is combined with the estimated entropy change of the reaction one obtains the quantitative lower limit D (CO₂+O⁻) −D (O₂+O⁻) ?0.58 eV. The reaction OH⁻+O₃→O⁻₃+OH is found to be fast, thereby establishing lower limits for the electron affinity of O₃ and the O⁻ bond dissociation energy of O⁻₃. When taken with the above limit for the relative CO⁻₃ and O⁻₃ bond dissociation energy one obtains lower limits for the electron affinity of CO₃ and the O⁻ bond dissociation energy of CO⁻₃. The latter lower limit does not overlap an upper limit for D (CO₂+O⁻) obtained from recent photodissociation studies. The relation of this discrepancy to the electron affinity of O₃ is discussed.