Dominance of large-scale atmospheric circulations in long-term variations of winter PM10 concentrations over East Asia

Abstract

Concentrations of wintertime particulate matters of diameters below 10 μm (PM 10 ) in South Korea and China have decreased since the 2000s largely owing to the emissions reduction policies of the two countries; however, this decreasing tendency has been notably weakened, or even been reversed, in recent years. This study examines the influence of large-scale atmospheric circulations on this PM 10 change over East Asia for the winters (December–February) of the 2004/05–2015/16 period using an empirical orthogonal function (EOF) analysis. The first EOF mode, which accounts for 32.7% of the total variance, indicates decreases in PM 10 concentrations until 2012 and thereafter increases in them particularly at most stations in eastern and northeastern China. Regression patterns of meteorological variables with respect to the first EOF time series indicate that the wintertime PM 10 variations over East Asia are greatly influenced by the Ural blocking; the weakening of the Ural blocking after 2014 led to the weakening of cold air flows from the north and provided atmospheric conditions favorable for bad air quality events over East Asia. The second EOF mode, which accounts for 20.1% of the total variance, shows a similar spatial distribution as the linear trend of PM 10 concentrations during the analysis period and would be related to the long-term changes in emissions. Our findings emphasize that the long-term variations in air quality over East Asia are affected primarily by the variations in large-scale atmospheric circulations with secondary contributions from the changes in emissions. • This study examines the influence of atmospheric circulation on PM 10 over East Asia. • The first EOF mode shows decrease in winter PM 10 until 2012 and increase thereafter. • Weakening of Ural blocking causes favorable condition for bad East Asian air quality. • The second EOF mode shows a similar distribution as the linear trend of winter PM 10 .