Investigation of factors controlling PM2.5 variability across the South Korean Peninsula during KORUS-AQ

Carolyn E Jordan; James H Crawford; Andreas J Beyersdorf; Thomas F Eck; Hannah S Halliday; Benjamin A Nault; Lim-Seok Chang; JinSoo Park; Rokjin Park; Gangwoong Lee; Hwajin Kim; Jun-Young Ahn; Seogju Cho; Hye Jung Shin; Jae Hong Lee; Jinsang Jung; Deug-Soo Kim; Meehye Lee; Taehyoung Lee; Andrew Whitehill; James Szykman; Melinda K Schueneman; Pedro Campuzano-Jost; Jose L Jimenez; Joshua P DiGangi; Glenn S Diskin; Bruce E Anderson; Richard H Moore; Luke D Ziemba; Marta A Fenn; Johnathan W Hair; Ralph E Kuehn; Robert E Holz; Gao Chen; Katherine Travis; Michael Shook; David A Peterson; Kara D Lamb; Joshua P Schwarz

doi:10.1525/elementa.424

Investigation of factors controlling PM_2.5 variability across the South Korean Peninsula during KORUS-AQ

Elementa (Wash D C). 2020;8(28):10.1525/elementa.424. doi: 10.1525/elementa.424.

Authors

Carolyn E Jordan^{1

2}, James H Crawford², Andreas J Beyersdorf^{2

3}, Thomas F Eck^{4

5}, Hannah S Halliday^{2

5

6}, Benjamin A Nault^{7

8}, Lim-Seok Chang⁹, JinSoo Park⁹, Rokjin Park¹⁰, Gangwoong Lee¹¹, Hwajin Kim^{12

13}, Jun-Young Ahn⁹, Seogju Cho¹⁴, Hye Jung Shin⁹, Jae Hong Lee¹⁵, Jinsang Jung¹⁶, Deug-Soo Kim¹⁷, Meehye Lee¹⁸, Taehyoung Lee¹¹, Andrew Whitehill¹⁹, James Szykman^{2

19}, Melinda K Schueneman^{7

8}, Pedro Campuzano-Jost^{7

8}, Jose L Jimenez^{7

8}, Joshua P DiGangi², Glenn S Diskin², Bruce E Anderson², Richard H Moore², Luke D Ziemba², Marta A Fenn^{2

20}, Johnathan W Hair², Ralph E Kuehn²¹, Robert E Holz²¹, Gao Chen², Katherine Travis^{2

5}, Michael Shook², David A Peterson²², Kara D Lamb^{8

23}, Joshua P Schwarz²³

Affiliations

¹ National Institute of Aerospace, Hampton, Virginia, US.
² NASA Langley Research Center, Hampton, Virginia, US.
³ California State University, San Bernardino, California, US.
⁴ NASA Goddard Space Flight Center, Greenbelt, Maryland, US.
⁵ Universities Space Research Association, Columbia, Maryland, US.
⁶ EPA, Research Triangle Park, North Carolina, US.
⁷ Department of Chemistry, University of Colorado, Boulder, Colorado, US.
⁸ Cooperative Institute for Research in the Environmental Sciences, University of Colorado, Boulder, Colorado, US.
⁹ National Institute of Environmental Research, Air Quality Research Division, Incheon, KR.
¹⁰ School of Earth and Environmental Sciences, Seoul National University, Seoul, KR.
¹¹ Hankuk University of Foreign Studies, Seoul, KR.
¹² Center for Environment, Health and Welfare Research, Korea Institute of Science and Technology, Seoul, KR.
¹³ Department of Energy and Environmental Engineering, University of Science and Technology, Daejeon, KR.
¹⁴ Seoul Metropolitan Government Research Institute of Public Health and Environment, Gyeonggi-do, KR.
¹⁵ Harim Engineering, Inc., Seoul, KR.
¹⁶ Center for Gas Analysis, Korea Research Institute of Standards and Science, Daejeon, KR.
¹⁷ Department of Environmental Engineering, Kunsan National University, Gunsan, KR.
¹⁸ Department of Earth and Environmental Sciences, Korea University, Seoul, KR.
¹⁹ US EPA/Office of Research and Development/Center for Environmental Measurement and Modeling, Research Triangle Park, North Carolina, US.
²⁰ Science Systems and Applications Inc., Hampton, Virginia, US.
²¹ Space Sciences Engineering Center, University of Wisconsin, Madison, Wisconsin, US.
²² U.S. Naval Research Laboratory, Monterey, California, US.
²³ NOAA Earth System Research Laboratory, Chemical Sciences Division, Boulder, Colorado, US.

Abstract

The Korea - United States Air Quality Study (May - June 2016) deployed instrumented aircraft and ground-based measurements to elucidate causes of poor air quality related to high ozone and aerosol concentrations in South Korea. This work synthesizes data pertaining to aerosols (specifically, particulate matter with aerodynamic diameters <2.5 micrometers, PM_2.5) and conditions leading to violations of South Korean air quality standards (24-hr mean PM_2.5 < 35 μg m^-3). PM_2.5 variability from AirKorea monitors across South Korea is evaluated. Detailed data from the Seoul vicinity are used to interpret factors that contribute to elevated PM_2.5. The interplay between meteorology and surface aerosols, contrasting synoptic-scale behavior vs. local influences, is presented. Transboundary transport from upwind sources, vertical mixing and containment of aerosols, and local production of secondary aerosols are discussed. Two meteorological periods are probed for drivers of elevated PM_2.5. Clear, dry conditions, with limited transport (Stagnant period), promoted photochemical production of secondary organic aerosol from locally emitted precursors. Cloudy humid conditions fostered rapid heterogeneous secondary inorganic aerosol production from local and transported emissions (Transport/Haze period), likely driven by a positive feedback mechanism where water uptake by aerosols increased gas-to-particle partitioning that increased water uptake. Further, clouds reduced solar insolation, suppressing mixing, exacerbating PM_2.5 accumulation in a shallow boundary layer. The combination of factors contributing to enhanced PM_2.5 is challenging to model, complicating quantification of contributions to PM_2.5 from local versus upwind precursors and production. We recommend co-locating additional continuous measurements at a few AirKorea sites across South Korea to help resolve this and other outstanding questions: carbon monoxide/carbon dioxide (transboundary transport tracer), boundary layer height (surface PM_2.5 mixing depth), and aerosol composition with aerosol liquid water (meteorologically-dependent secondary production). These data would aid future research to refine emissions targets to further improve South Korean PM_2.5 air quality.

Keywords: Aerosols; Air quality; KORUS-AQ; PM2.5; South Korea.

Grants and funding

EPA999999/ImEPA/Intramural EPA/United States