Applicability of the steady state approximation to the interpretation of atmospheric observations of NO3 and N2O5

Abstract

This paper examines the conditions under which a steady state analysis is valid for modeling NO₃ and N₂O₅ chemistry in the atmosphere. The conclusions come from a simple box model analysis that considers a limited number of reactions between NO₂, O₃, NO₃, N₂O₅ and the presumed sinks for the latter two. The applicability of the steady state depends on the strength of the sinks for NO₃ and N₂O₅, the concentration of NO₂, and the ambient temperature. Under clean conditions, weak sinks for NO₃ prevent the system from passing through the induction period during the time between sunset and sunrise, thus keeping the system out of steady state. Under polluted (i.e., large NO₂ concentrations) or cold conditions, the presence of an equilibrium between NO₃ and N₂O₅ markedly slows the approach to steady state even though the two species are close to equilibrium. The time required to approach equilibrium between NO₂, NO₃, and N₂O₅ is not a good measure of the time required to achieve a steady state among these compounds. The paper considers the conditions for which steady state may be valid and outlines a method for identification of individual sinks for NO₃ and N₂O₅ from observed concentration measurements for the steady state case.