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Abstract. Tropospheric ozone is a major air pollutant and greenhouse gas. It is also the primary precursor of OH, the main tropospheric oxidant. Global atmospheric chemistry models show large differences in their simulations of tropospheric ozone budgets. Here we implement the widely used GEOS-Chem atmospheric chemistry module as an alternative to CAM-chem within the Community Earth System Model version 2 (CESM2). We compare the resulting simulations of tropospheric ozone and related species to observations from ozonesondes, the ATom-1 aircraft campaign over the Pacific and Atlantic, and the KORUS-AQ aircraft campaign over the Seoul Metropolitan Area. We find that GEOS-Chem and CAM-chem within CESM2 have similar tropospheric ozone budgets and concentrations usually within 5 ppb but important differences in the underlying processes including (1) photolysis scheme (no aerosol effects in CAM-chem), (2) aerosol nitrate photolysis, (3) N2O5 cloud uptake, (4) tropospheric halogen chemistry, and (5) ozone deposition to the oceans. Global tropospheric OH concentrations are the same in both models but there are large regional differences reflecting the above processes. Carbon monoxide is lower in CAM-chem (and lower than observations) because of higher OH concentrations in the northern hemisphere and insufficient production from isoprene oxidation in the southern hemisphere. CESM2 does not scavenge water-soluble gases in convective updrafts leading to some upper tropospheric biases. Comparison to KORUS-AQ observations shows successful simulation of oxidants under polluted conditions in both models but suggests insufficient boundary layer mixing in CESM2. The implementation and evaluation of GEOS-Chem in CESM2 contributes to the MUSICA vision of modularizing tropospheric chemistry in Earth system models.
Lin et al. (Wed,) studied this question.