Absolute rate constant and O(³P) yield for the O(¹D)+N₂O reaction in the temperature range 227 K to 719 K

Abstract. The absolute rate constant for the reaction that is the major source of stratospheric NO_x, O(¹D)+N₂O → products, has been determined in the temperature range 227 K to 719 K, and, in the temperature range 248 K to 600 K, the fraction of the reaction that yields O(³P). Both the rate constants and product yields were determined using a recently-developed chemiluminescence technique for monitoring O(¹D) that allows for higher precision determinations for both rate constants, and, particularly, O(³P) yields, than do other methods. We found the rate constant, k_R1, to be essentially independent of temperature between 400 K and 227 K, having a value of (1.37±0.11)×10⁻¹⁰ cm³ s⁻¹, and for temperatures greater than 450 K a marked decrease in rate constant was observed, with a rate constant of only (0.94±0.11)×10⁻¹⁰ cm³ s⁻¹ at 719 K. The rate constants determined over the 227 K–400 K range show very low scatter and are significantly greater, by 20% at room temperature and 15% at 227 K, than the current recommended values. The fraction of O(³P) produced in this reaction was determined to be 0.002±0.002 at 250 K rising steadily to 0.010±0.004 at 600 K, thus the channel producing O(³P) can be entirely neglected in atmospheric kinetic modeling calculations. A further result of this study is an expression of the relative quantum yields as a function of temperature for the chemiluminescence reactions (k_CL1)C₂H + O(¹D) → CH(A) + CO and (k_CL2)C₂H + O(³P) → CH(A) + CO, both followed by CH(A) → CH(X) + hν, as k_CL1(T)/k_CL2(T)=(32.8T−3050)/(6.29T+398).