Abstract
Mass concentrations of chemical constituents (organics, nitrate, sulfate, ammonium, chloride, and black carbon (BC)) and the number size distribution of submicrometer particles in the ambient atmosphere were continuously measured in urban Gwangju, Korea, during the Megacity Air Pollution Studies (MAPS)-Seoul campaign. Organics (9.1 μg/m3) were the most dominant species, followed by sulfate (4.7 μg/m3), nitrate (3.2 μg/m3), ammonium (2.6 μg/m3), and BC (1.3 μg/m3) in submicrometer particles (particulate matter less than 1 μm (PM1)). The potential source regions of the sulfate were located in the South and East regions of China and South and East regions of Korea, while local sources were responsible for the elevated BC concentration. Diurnal variation showed that concentrations of organics, nitrate, ammonium, chloride, and BC decreased with increasing mixing layer and wind speed (dilution effect), while sulfate and oxidized organics increased possibly due to their strong photochemical production in the afternoon. During the campaign, an elevated mass concentration of PM1 (PM1 event) and number concentration (nanoparticle formation (NPF) event) were observed (one PM1 event and nine NPF events out of 28 days). The PM1 event occurred with Western and Southwestern air masses with increasing sulfate and organics. Long-range transported aerosols and stagnant meteorological conditions favored the elevated mass concentration of submicrometer particles. Most of the NPF events took place between 10:00 and 14:00, and the particle growth rates after the initial nanoparticle formation were 7.2–11.0 nm/h. The times for increased concentration of nanoparticles and their growth were consistent with those for elevated sulfate and oxidized organics in submicrometer particles under strong photochemical activity.
Highlights
IntroductionFine particulate matter (PM) in the ambient atmosphere is of current interest due to its effects on climate change (radiation balance and cloud formation) [1] and human health [2,3,4]
Fine particulate matter (PM) in the ambient atmosphere is of current interest due to its effects on climate change [1] and human health [2,3,4]
It has often been observed that the chemical constituents in PM less than 1 μm (PM1 ) or 2.5 μm (PM2.5 ) were dependent on the types of long-range transported air mass arriving at sites [7,8,11,12]
Summary
Fine particulate matter (PM) in the ambient atmosphere is of current interest due to its effects on climate change (radiation balance and cloud formation) [1] and human health [2,3,4]. Atmosphere 2018, 9, 393 to better understand their sources and formation pathways when elevated PM mass and number concentrations are observed. Long-range transport (LTP) aerosols play an important role in the elevated mass concentration of submicrometer particles in East Asia [8,9,10]. Mass concentrations of organics, nitrate, sulfate, ammonium, chloride, and black carbon (BC) of submicrometer particles and the number size distribution of particles from 10 nm to 25 μm in an urban atmosphere (Gwangju, Korea) were continuously measured during the period of the Megacity Air Pollution Studies (MAPS)-Seoul 2015 campaign (18 May 2015–14 June 2015). Air mass backward trajectory analysis, residence time analysis (RTA), and potential source contribution function (PSCF) methods were applied to examine the effects of long-range transported aerosols on elevated. Number size distribution data were used to examine NPF in relation to the chemical composition of submicrometer particles and meteorological parameters
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