Apportioning and Locating PM_(2.5) Sources Affecting Coastal Cities: Ulsan in South Korea and Dalian in China

• Published in: Aerosol and Air Quality Research Vol. 24; no. 8
• Main Authors: Eunhwa Choi, Kwonho Jeon, Young Su Lee, Jongbae Heo, Ilhan Ryoo, Taeyeon Kim, Chuanlong Zhou, Philip K. Hopke, Seung-Muk Yi
• Format: Journal Article
• Language: English
• Published: 社團法人台灣氣膠研究學會 01.08.2024
• Subjects: Simplified quantitative transport bias analysis; Potential source contribution function; PM_(2.5); Source apportionment; Positive matrix factorization
• ISSN: 1680-8584
• DOI: 10.4209/aaqr.240031

PM_(2.5) mass and its constituent species were analyzed in two coastal cities (Ulsan, South Korea, and Dalian, China) between July 13, 2018, and September 20, 2019. Ten and nine sources were identified in Ulsan and Dalian, respectively, using positive matrix factorization (PMF). In Ulsan, three sources (secondary nitrate [SN], secondary sulfate [SS], and traffic) contributed ~83.0% of the PM_(2.5) mass concentration (23.7 µg m^(-3)) during the heating period. In Dalian, four sources (SN, SS, traffic, and residential burning) accounted for ~84.3% of the total PM_(2.5) mass concentration (47.8 µg m^(-3)). Higher contributions of residential burning in Dalian (11.7 µg m^(-3)) than biomass burning in Ulsan (0.22 µg m^(-3)) were resolved during the heating period as was a higher proportion of SS contributions in Ulsan (6.28 µg m^(-3), 41.6%) than in Dalian (6.42 µg m^(-3), 21.2%) during non-heating period. Squared correlation coefficients (r^2) of sources common to the two cities were examined for lag times from -2 days to +4 days from Dalian to Ulsan. The largest r^2 of PM_(2.5) mass concentrations during the heating period was 0.34 on Lag day 1. The same day, largest r^2 during the non-heating period was 0.14 indicating, stronger, lagged PM_(2.5) correlations during the heating period. The SN, SS, soil, and oil combustion sources, with r^2 values of 0.25, 0.20, 0.41, and 0.25, respectively, show fair correlations between the cities for these sources during the heating period. Probable source locations were identified by simplified quantitative transport bias analysis (SQTBA) and potential source contribution function (PSCF) as a multiple site approach and a single site approach, respectively. Weaker correlations of SN (r^2 = 0.15) and SS (r^2 ＜ 0.1) during the non-heating period were supported by the different probable source locations. This study identified the sources requiring individual national and/or joint international efforts to reduce ambient PM_(2.5) in these neighboring countries.