Abstract
Abstract. During the Asian summer monsoon, the circulation in the upper troposphere/lower stratosphere (UTLS) is dominated by the Asian monsoon anticyclone (AMA). Pollutants convectively uplifted to the upper troposphere are trapped within this anticyclonic circulation that extends from the Pacific Ocean to the Eastern Mediterranean basin. Among the uplifted pollutants are ozone (O3) and its precursors, such as carbon monoxide (CO) and nitrogen oxides (NOx). Many studies based on global modeling and satellite data have documented the source regions and transport pathways of primary pollutants (CO, HCN) into the AMA. Here, we aim to quantify the O3 budget by taking into consideration anthropogenic and natural sources. We first use CO and O3 data from the MetOp-A/IASI sensor to document their tropospheric distributions over Asia, taking advantage of the useful information they provide on the vertical dimension. These satellite data are used together with MOZAIC tropospheric profiles recorded in India to validate the distributions simulated by the global GEOS-Chem chemistry transport model. Over the Asian region, UTLS monthly CO and O3 distributions from IASI and GEOS-Chem display the same large-scale features. UTLS CO columns from GEOS-Chem are in agreement with IASI, with a low bias of 11 ± 9 % and a correlation coefficient of 0.70. For O3, the model underestimates IASI UTLS columns over Asia by 14 ± 26 % but the correlation between both is high (0.94). GEOS-Chem is further used to quantify the CO and O3 budget through sensitivity simulations. For CO, these simulations confirm that South Asian anthropogenic emissions have a more important impact on enhanced concentrations within the AMA (∼ 25 ppbv) than East Asian emissions (∼ 10 ppbv). The correlation between enhanced emissions over the Indo-Gangetic Plain and monsoon deep convection is responsible for this larger impact. Consistently, South Asian anthropogenic NOx emissions also play a larger role in producing O3 within the AMA (∼ 8 ppbv) than East Asian emissions (∼ 5 ppbv), but Asian lightning-produced NOx is responsible for the largest O3 production (10–14 ppbv). Stratosphere-to-troposphere exchanges are also important in transporting O3 in the upper part of the AMA.
Highlights
Tropospheric O3 plays an important role in determining the radiative budget of the atmosphere and has a non-negligible impact on climate change
The northern-hemispheric tropical tropospheric circulation is dominated by the Asian summer monsoon (ASM), which is characterized by a strong southwesterly flow in the lower troposphere converging over South and Southeast Asia and results in deep convective activity over this region
This is confirmed by the longitude–pressure cross sections averaged over the 21–29◦ N band that correspond to the southern part of the Asian monsoon anticyclone (AMA) (Fig. 2), where we notice that the averaging kernels (AvK) smoothing mixes the upper troposphere/lower stratosphere (UTLS) enhanced concentrations throughout the middle and upper troposphere, leading to a better agreement with IASI cross sections
Summary
Tropospheric O3 plays an important role in determining the radiative budget of the atmosphere and has a non-negligible impact on climate change. Using high-resolution WRF meteorological forcing for back trajectory simulations, Heath and Fuelberg (2014) have demonstrated that most of the air parcels convectively uplifted from the PBL and ending up in the AMA at 100 hPa originate in the Tibetan Plateau or the Himalayan southern slopes These studies based on Lagrangian modeling are not able to document the origin of pollutants in the AMA, which depends on the distribution of their sources. Based on CTM sensitivity simulations, Kunhikrishnan et al (2004) have quantified the impact of surface NOx from India and the neighboring regions on the O3 budget over India Their results show that O3 in the Indian middle–upper troposphere (500–150 hPa) during the monsoon is mostly produced by regional (Indian) NOx emissions uplifted by convection.
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