Comment on amt-2022-167

Abstract

An aerosol flow tube system coupled with detailed box model was newly developed to measure N2O5 heterogeneous uptake coefficients (γ(N2O5)) on ambient aerosols directly. This system features simultaneous measurements of N2O5 concentration at the both entrance and exit of the flow tube to ensure an accurate derivation of N2O5 loss in the flow tube. Simulation and laboratory tests demonstrate that this flow tube system is able to overcome the interference from side reactions led by varying reactants (e.g., NO2, O3 and NO) and improve the robustness of results with the assistance of box model method . Factors related to γ(N2O5) derivation were extensively characterized, including particle transmission efficiency, mean residence time in the flow tube and wall loss coefficient of N2O5, for normal operating condition. The measured γ(N2O5) on (NH4)2SO4 model aerosols were in good agreement with literature values over a range of relative humidity (RH). The detection limit of γ(N2O5) was estimated to be 0.0016 at low aerosol surface concentration (Sa) condition of 200 μm2 cm-3. Given the instrument uncertainties and potential fluctuation of air mass between successive sampling modes, we estimate the overall uncertainty of γ(N2O5) that ranges from 16 to 74 % for different ambient conditions. This flow tube system was then successfully deployed for field observations at an urban site of Beijing influenced by anthropogenic emissions. The performance in field observation demonstrates that the current setup of this system is capable of obtaining robust γ(N2O5) amid the switch of air mass.