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  • Title: [Characteristics of Water-soluble Ion Pollution in PM2.5 and the Causes of High Acidity of PM2.5 in Dalian].
    Author: Yang M, Liu C, Wang XH, Liu LL, Zhang MM, Cao SS, Yan SZ, Sun ZY, Tian CG.
    Journal: Huan Jing Ke Xue; 2024 Sep 08; 45(9):5127-5139. PubMed ID: 39323131.
    Abstract:
    To gain a deeper understanding of the pollution status and influencing factors of fine particles (PM2.5) and their water-soluble ions (WSI) in Dalian and to implement precise control of pollution events such as haze and acid rain, PM2.5 samples were collected in Dalian from June 2021 to May 2022. Then, the mass concentrations of PM2.5 and WSI were determined using the weight method and ion chromatography, respectively, and the pollution characteristics and sources were analyzed. Furthermore, the causes of the high acidity of PM2.5 in spring were discussed. The results showed that the annual average mass concentrations of PM2.5 and WSI in Dalian during the sampling period were (33.24 ±28.87) μg·m-3 and (18.66 ±20.52) μg·m-3, respectively, and the secondary ions (SNA, including SO42-, NO3-, and NH4+) accounted for the highest proportion of WSI [(86.2 ±9.3)%]. The order of ion concentration levels from highest to lowest was: NO3->SO42->NH4+>Cl->K+>Ca2+>Na+>Mg2+>F-. Due to the influence of meteorological conditions and coal combustion emissions during the concentrated heating period from late autumn to early spring, the seasonal variation in PM2.5 and WSI was winter>spring>autumn>summer, whereas SNA was the highest in spring and the lowest in summer. The results of correlation and principal component analysis showed that WSI in PM2.5 was mainly from the secondary transformation of atmospheric SO2 and NO2 (contributing to the majority of SNA), mixed sources of combustion and dust (characterized by K+, Mg2+, Cl-, and F-), and sources of sand and sea salt (characterized by Na+, Ca2+, and Mg2+). In summer, the main combustion source was biomass burning, whereas in autumn, winter, and spring, coal combustion emissions were predominant. The change in wind direction from autumn to winter brought by a shift from the source of sea salt to soil dust; additionally, the external pollution transported by northwest winds contributed to the complexity of the sources of WSI in PM2.5 during spring in Dalian. ISORROPIA-II model simulations suggested NH4NO3 as the most present solid aerosol form in PM2.5 in Dalian, followed by CaSO4 and (NH42SO4; compared to that in solid aerosols, more SNA existed in liquid aerosols. The annual average pH of PM2.5 in Dalian was 5.65 ±3.00, with pH values close to neutral in summer, autumn, and winter but significantly acidic in spring (2.03 ±3.18). The high acidity observed in spring was attributed to the combination of low temperature, high humidity, and high SNA concentrations. These conditions resulted in higher aerosol water content and increased gas-to-particle conversion rates, ultimately leading to an ammonia-deficient environment. The backward trajectory and PSCF results indicated that the external transport of high acidity PM2.5 in spring mainly came from the northwest (45.0%) and southwest (40.8%) directions. Mobile source emissions made the most significant contribution to the transportation of pollutants in the former, forming high-pollution source areas in the Beijing-Tianjin-Hebei Region, which may have been mainly related to urban motor vehicle and port vessel emissions; the latter was influenced by relatively strong stationary sources and showed higher SO2 emissions in the southern part of Henan Province and the central part of Jiangsu Province.
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