Observations of the vertical distributions of summertime atmospheric pollutants in Nam Co: OH production and source analysis

The Tibetan Plateau (TP) plays a key role in regional environment and global climate change, however, the lack of vertical observation hinders a deeper understanding of the atmospheric chemistry and atmospheric oxidation capacity (AOC) on the TP. In this study, we conducted MAX-DOAS measurements at Nam Co, central TP, to observe the vertical profiles of aerosol, water vapor, NO₂, HONO and O₃ from May to July 2019. In addition to NO₂ mainly exhibiting a Gaussian shape with the maximum value appearing at 300-400 m, other four species all showed an exponential shape and decreased with the increase of height. The maximum values of monthly averaged aerosol (0.17 km^-1) and O₃ (66.71 ppb) occurred on May, water vapor (3.68×10¹⁷ molec cm^-3) and HONO (0.13 ppb) appeared on July, while NO₂ (0.39 ppb) occurred on June at 200-400 m layer. Water vapor, HONO and O₃ all exhibited a multi-peak pattern, and aerosol appeared a bi-peak pattern for their averaged diurnal variation. Moreover, we found O₃ and HONO were the main contributors to OH on the TP. The averaged vertical profiles of OH production rates from O₃ and HONO all exhibited an exponential shape, and decreased with the increase of height with the maximum values of 2.61 ppb/h and 0.49 ppb/h at the bottom layer, respectively. In addition, source analysis for HONO and O₃ were conducted based on vertical observations. The heterogeneous reaction of NO₂ on wet surfaces was a significant source of HONO, which obviously associated with water vapor concentration and aerosol extinction. The maximum values of HONO/NO₂ appeared around water vapor being 1.0×10¹⁷ molec cm^-3 and aerosol being lager 0.15 km^-1 under 1.0 km, and the maximum values usually accompanied with water vapor being 1.0-2.0×10¹⁷ molec cm^-3 and aerosol being lager 0.02 km^-1 at 1.0-2.0 km. O₃ was potentially sourced from south Asian subcontinent and Himalayas through long-range transport. Our results enrich the new understanding of vertical distribution of atmospheric components and explained the strong AOC on the TP.