Abstract
Abstract. Aerosols have significantly affected health, environment, and climate in Europe. Aerosol concentrations have been declining since the 1980s in Europe, mainly owing to a reduction of local aerosol and precursor emissions. Emissions from other source regions of the world, which have been changing rapidly as well, may also perturb the historical and future trends of aerosols and change their radiative impact in Europe. This study examines trends of aerosols in Europe during 1980–2018 and quantifies contributions from 16 source regions using the Community Atmosphere Model version 5 with Explicit Aerosol Source Tagging (CAM5-EAST). The simulated near-surface total mass concentration of sulfate, black carbon, and primary organic carbon had a 62 % decrease during 1980–2018. The majority of which was contributed to reductions of local emissions in Europe, and 8 %–9 % was induced by a decrease in emissions from Russia–Belarus–Ukraine. With the decreases in the fractional contribution of local emissions, aerosols transported from other source regions are increasingly important for air quality in Europe. During 1980–2018, the decrease in sulfate loading led to a warming effect of 2.0 W m−2 in Europe, with 12 % coming from changes in non-European sources, especially from North America and Russia–Belarus–Ukraine. According to the Shared Socioeconomic Pathways (SSP) scenarios, contributions to the sulfate radiative forcing over Europe from both local European emissions and non-European emissions should decrease at a comparable rate in the next 3 decades, suggesting that future changes in non-European emissions are as important as European emissions for causing possible regional climate change associated with aerosols in Europe.
Highlights
Aerosols are the main air pollutants that contribute to excess morbidity and premature mortality by damaging cardiovascular and respiratory systems (Lelieveld et al, 2019)
Total sulfate-black carbon (BC)-primary organic aerosol (POA) concentrations decreased during 1980–2018 over all of the four subregions of Europe (Fig. 7) since near-surface aerosol concentrations in Europe are dominated by its local emissions and the European anthropogenic emissions have significantly decreased during this time period
Using a global aerosol–climate model with an explicit aerosol source tagging technique (CAM5-Explicit Aerosol Source Tagging (EAST)), we examine the long-term trends and source apportionment of aerosols in Europe for 1980–2018 from 16 source regions covering the globe in this study
Summary
Aerosols are the main air pollutants that contribute to excess morbidity and premature mortality by damaging cardiovascular and respiratory systems (Lelieveld et al, 2019). Source region contributions to European CO and O3 levels, as well as global and regional aerosol radiative forcing, were examined under the Hemispheric Transport of Air Pollution model experiment phase 2 (HTAP2) protocol, in which sensitivity simulations were conducted with reductions in anthropogenic emissions from different source regions by 20 % (Stjern et al, 2016; Jonson et al, 2018). This method suffers from a large computational cost for the excessive model simulations when estimating contributions from a large number of sources, and contributions from all sources do not sum up to 100 % of the total concentration in the default simulation (Koo et al, 2009; Wang et al, 2014).
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