Influence of the Asian Dust to the Air Quality in US During the spring season, the desert regions in Mongolia and China, especially Gobi desert in Northwest.

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Presentation transcript:

Influence of the Asian Dust to the Air Quality in US During the spring season, the desert regions in Mongolia and China, especially Gobi desert in Northwest China, are important sources of mineral aerosols over both Eastern Asia and the Northern Pacific Ocean Recent work suggests that the frequency of dust storms in China has apparently increased in the last several decades Aerosol particles emitted from the Northwest desert region of China may be transported to the remote Pacific Ocean, and may have a significant influence on the aerosol loadings and chemical speciation over large areas of Eastern Asia, the Northern Pacific and even as far away as North America Satellite images indicate that Asian dust is transported to US in the spring more frequently in the recent years

Asian Dust Episode (4/26/2001)

Origin of the Asian Dust Strong low pressure system sitting in northeast Mongolia caused surface wind speeds to be as high as ~30 m/s

Transport of the Asian dust to the United States The common weather conditions are usually associated with the upper low pressure trough / cut-ff low and surface low pressure system (low formed by a strong cyclonic vortex) over northeast China and north Korea [Kim et al., 2002]. Under this weather conditions, Asian dust can move fast along the zonal wind distribution due to the jet streak [Kim et al., 2002].

Influence of the Asian Dust to the Aerosol Properties in the United States

Development of the Ridge Helped Dust Deposition

Large Area Regional Haze on April 16, of the 68 WRAP IMPROVE monitoring sites were in 20% worst case days of the year For the sites that were 20% worst case days, the average contribution of fine soil to PM 2.5 is ~60% (with a standard deviation of 13%), and dusts (fine soil and coarse mass) contributed in average ~ 46% (S.D. 13%) to the aerosol light extinction. The average contribution of fine soil to PM 2.5 is ~54% (with a standard deviation of 18%) for all WRAP sites on April 16, 2001.

K/Fe = 0.5 (0.05) lower than the value of 0.6 for the local dust [IMPROVE website], but higher than the value reported for the African dust Dust Signature?

Summary Given suitable weather conditions, dust can be lifted from the dry surface of the Asian Gobi desert region and transported to the United States in about 7-10 days. It may cause haze in a large area and last several days depending on the regional and local weather conditions in the United States. The origin of the Asian dust usually associated with low pressure system in the Gobi desert region of Mongolia and northwest China. Once elevated to the troposphere, Asian dust can move fast along the zonal wind distribution due to the jet streak. Under ridge of high pressure, large-scale deposition of dust from troposphere to the boundary layer may happen and result in elevated aerosol concentrations. The fine soil concentrations on April 16 were about 5 times higher than the 5 year ( ) April averages. The contributions of fine soil and coarse mass to aerosol light extinction increased from 7% and 15% to 21% and 20% for 5 year April average and April 16 Although it is very difficult to quantitatively separate the influence of the Asian dust from the local dust and dust transported from other regions of the world (e.g. Africa), some signatures may be identified based on the ratios of the dust elements and the ratio of fine soil to coarse mass concentrations