Impact of particulate nitrate photolysis on air quality over the Northern Hemisphere.

We use the Community Multiscale Air Quality (CMAQv5.4) model to examine the potential impact of particulate nitrate (pNO) photolysis on air quality over the Northern Hemisphere. We estimate the photolysis frequency of pNO by scaling the photolysis frequency of nitric acid (HNO) with an enhancement factor that varies between 10 and 100 depending on pNO and sea-salt aerosol concentrations and then perform CMAQ simulations without and with pNO photolysis to quantify the range of impacts on tropospheric composition. The photolysis of pNO produces gaseous nitrous acid (HONO) and nitrogen dioxide (NO) over seawater thereby increasing atmospheric HONO and NO mixing ratios. HONO subsequently undergoes photolysis, producing hydroxyl radicals (OH). The increase in NO and OH alters atmospheric chemistry and enhances the atmospheric ozone (O) mixing ratio over seawater, which is subsequently transported to downwind continental regions. Seasonal mean model O vertical column densities without pNO photolysis are lower than the Ozone Monitoring Instrument (OMI) retrievals, while the column densities with the pNO photolysis agree better with the OMI retrievals of tropospheric O burden. We compare model O mixing ratios with available surface observed data from the U.S., Japan, the Tropospheric Ozone Assessment Report - Phase II, and OpenAQ; and find that the model without pNO photolysis underestimates the observed data in winter and spring seasons and the model with pNO photolysis improves the comparison in both seasons, largely rectifying the pronounced underestimation in spring. Compared to measurements from the western U.S., model O mixing ratios with pNO photolysis agree better with observed data in all months due to the persistent underestimation of O without pNO photolysis. Compared to the ozonesonde measurements, model O mixing ratios with pNO photolysis also agree better with observed data than the model O without pNO photolysis.