Global sensitivities of reactive N and S gas and particle concentrations and deposition to precursor emissions reductions.

The reduction of fine particles (PM 2.5) and reactive N (N r) and S (S r) species is a key objective for air pollution control policies because of their major adverse effects on human health, ecosystem diversity, and climate. The sensitivity of global and regional N r , S r , and PM 2.5 to 20 % and 40 % individual and collective reductions in anthropogenic emissions of NH 3 , NO x , and SO x (with respect to a 2015 baseline) is investigated using the EMEP MSC-W (European Monitoring and Evaluation Programme Meteorological Synthesizing Centre – West) atmospheric chemistry transport model with WRF (Weather Research and Forecasting) meteorology. Regional comparisons reveal that the individual emissions reduction has multiple co-benefits and small disbenefits on different species, and those effects are highly geographically variable. A 40 % NH 3 emission reduction decreases regional average NH 3 concentrations by 47 %–49 % but only decreases NH 4+ by 18 % in Euro_Medi, 15 % in East Asia, 12 % in North America, and 4 % in South Asia. This order follows the regional ammonia richness. A disbenefit is the increased SO 2 concentrations in these regions (10 %–16 % for 40 % reductions) because reduced NH 3 levels decrease SO 2 deposition through altering atmospheric acidity. A 40 % NO x emission reduction reduces NO x concentrations in East Asia by 45 %, Euro_Medi and North America by ∼ 38 %, and South Asia by 22 %, whilst the regional order is reversed for fine NO 3- , which is related to enhanced O 3 levels in East Asia (and also, but by less, in Euro_Medi) and decreased O 3 levels in South Asia (and also, but by less, in North America). Consequently, the oxidation of NO x to NO 3- and of SO 2 to SO 42- is enhanced in East Asia but decreased in South Asia, which causes a less effective decrease in NO 3- and even an increase in SO 42- in East Asia but quite the opposite in South Asia. For regional policy making, it is thus vital to reduce three precursors together to minimize such adverse effects. A 40 % SO x emission reduction is slightly more effective in reducing SO 2 (42 %–45 %) than SO 42- (34 %–38 %), whilst the disbenefit is that it yields a ∼ 12 % increase in total NH 3 deposition in the four regions, which further threatens ecosystem diversity. This work also highlights important messages for policy makers concerning the mitigation of PM 2.5. More emissions controls focusing on NH 3 and NO x are necessary for regions with better air quality, such as northern Europe and eastern North America. In East Asia, the three individual reductions are equally effective, whilst in South Asia only SO x reduction is currently effective. The geographically varying non-one-to-one proportionality of chemical responses of N r , S r , and PM 2.5 to emissions reductions revealed by this work show the importance of both prioritizing emissions strategies in different regions and combining several precursor reductions together to maximize the policy effectiveness. [ABSTRACT FROM AUTHOR]