Abstract
The International Maritime Organization (IMO) has formulated stringent ship emission regulations, and the global fuel sulfur limit of 0.50% became effective in 2020. Kitakyushu City is in the coastal suburbs of western Japan, and PM2.5 had already decreased prior to the global low-sulfur regulation, with concentrations in 2017, 2018, and 2019 of 12.2, 13.4, and 8.1 µg·m−3, respectively. The loading particles of the air masses passing through the Bohai Sea, Yellow Sea, and East China Sea in 2019 decreased to 3.4 µg·m−3, which was obviously higher than that of other air masses (0.5 µg·m−3), and the contribution of nss-SO42− could reach 56%, followed by OC (23%) and NH4+ (21%). Moreover, the characteristics of typical ship-emitted metals (V, Ni, As, Sb, W, and Cd) also changed greatly. Their sum concentrations in 2017, 2018, and 2019 were 10.6, 11.1, and 6.9 ng·m−3, respectively, which showed an annual variation similar to that of nss-SO42−. As for the particle exposure risk, the lowest chronic effect and carcinogenic risk were observed in 2019, with hazard indices (HI) for adults and children of 0.9 and 7.6, and carcinogenic risks (CRs) of 3.8 × 10−5 and 8.4 × 10−5, respectively. In this study, the health risks as well as air quality prior to the enforcement of the MARPOL Treaty in the leeward area of the Asian continent were totally and more precisely studied and evaluated based on the annual dataset; revealing the influence of trans-boundary transportation under individual Chinese regulations on the particle characteristic variations in Kitakyushu, Japan.
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References
Agrawal H, Welch WA, Miller JW, Cocker DR (2008) Emission measurements from a crude oil tanker at sea. Environ Sci Technol 42:7098–7103
Aikawa M, Morino Y, Kajino M, Hiraki T, Horie Y, Nakatsubo R, Matsumura C, Mukai H (2016) Candidates to provide a specific concentration difference for ambient sulfur and nitrogen compounds near the coastal and roadside sites of Japan. Water Air Soil Pollut 227:353
Aikawa M, Hiraki T, Horie Y, Nakatsubo R, Matsumura C, Mukai H (2017) Trans-boundary and in-country transport of air pollutants observed in Kobe, Japan by high frequent filter pack sampling method. J Atmos Chem 74:505–518
Al-Enazi A, Okonkwo EC, Bicer Y, Al-Ansari T (2021) A review of cleaner alternative fuels for maritime transportation. Energy Rep 7:1962–1985
Anastasopolos AT, Sofowote UM, Hopke PK, Rouleau M, Shin T, Dheri A, Peng H, Kulka R, Gibson MD, Farah PM, Sundar N (2021) Air quality in Canadian port cities after regulation of low-sulphur marine fuel in the North American Emissions Control Area. Sci Total Environ 791:147949
Chen D, Wang X, Nelson P, Li Y, Zhao N, Zhao Y, Lang J, Zhou Y, Guo X (2017) Ship emission inventory and its impact on the PM2.5 air pollution in Qingdao Port, North China. Atmos Environ 166:351–361
Eyring V, Isaksen ISA, Berntsen T, Collins WJ, Corbett JJ, Endresen O, Grainger RG, Moldanova J, Schlager H, Stevenson DS (2010) Transport impacts on atmosphere and climate: shipping. Atmos Environ 44:4735–4771
Fan MY, Zhang YL, Lin YC, Cao F, Sun Y, Qiu Y, Xing G, Dao X, Fu P (2021) Specific sources of health risks induced by metallic elements in PM2.5 during the wintertime in Beijing, China. Atmos Environ 246:118112
Fang W, Yang Y, Xu Z (2013) PM10 and PM2.5 and health risk assessment for heavy metals in a typical factory for cathode ray tube television recycling. Environ Sci Technol 47:12469–12476
González Y, Rodríguez S, Guerra García JC, Trujillo JL, García R (2011) Ultrafine particles pollution in urban coastal air due to ship emissions. Atmos Environ 45:4907–4914
Japan Ministry of the Environment (2019) PM2.5 components measurement manual. https://www.env.go.jp/air/osen/pm/ca/manual.html. Accessed 09.02.2021
Kattner L, Mathieu-Üffing B, Burrows JP, Richter A, Schmolke S, Seyler A, Wittrock F (2015) Monitoring compliance with sulfur content regulations of shipping fuel by in situ measurements of ship emissions. Atmos Chem Phys 15:10087–10092
Kondo M, Ishda A, Hiramoto T, Nakazono A, Ono S, Nakatsubo R, Futamura A, Oshita Y, Zhang X, Aikawa M (2023) Sudden decrease of airborne sulfates in summer at sites in western Japan prior to the enforcement of the MARPOL Treaty. Atmos Environ 295:119571
Kosowska-Stamirowska Z (2020) Network effects govern the evolution of maritime trade. Proc Natl Acad Sci 117:12719
Kumar S, Raman RS (2016) Inorganic ions in ambient fine particles over a National Park in central India: seasonality, dependencies between SO42-, NO3-, and NH4+, and neutralization of aerosol acidity. Atmos Environ 143:152–163
Lee HJ, Yoo SH, Huh SY (2020) Economic benefits of introducing LNG-fuelled ships for imported flour in South Korea. Transp Res D: Transp Environ 78:102220
Lehtoranta K, Aakko-Saksa P, Murtonen T, Vesala H, Ntziachristos L, Rönkkö T, Karjalainen P, Kuittinen N, Timonen H (2019) Particulate mass and nonvolatile particle number emissions from marine engines using low-sulfur fuels, natural gas, or scrubbers. Environ Sci Technol 53:3315–3322
Liu Z, Zhang H, Zhang Y, Liu X, Ma Z, Xue L, Peng X, Zhao J, Gong W, Peng Q, Du J, Wang J, Tan Y, He L, Sun Y (2022) Characterization and sources of trace elements in PM1 during autumn and winter in Qingdao, Northern China. Sci Total Environ 811:151319
Matthias V, Bewersdorff I, Aulinger A, Quante M (2010) The contribution of ship emissions to air pollution in the North Sea regions. Environ Pollut 158:2241–2250
Megido L, Suárez-Peña B, Negral L, Castrillón L, Fernández-Nava Y (2017) Suburban air quality: human health hazard assessment of potentially toxic elements in PM10. Chemosphere 177:284–291
MohseniBandpi A, Eslami A, Ghaderpoori M, Shahsavani A, Jeihooni AK, Ghaderpoury A, Alinejad A (2018) Health risk assessment of heavy metals on PM2.5 in Tehran air, Iran. Data Brief 17:347–355
Moldanová J, Fridell E, Winnes H, Holmin-Fridell S, Boman J, Jedynska A, Tishkova V, Demirdjian B, Joulie S, Bladt H, Ivleva NP, Niessner R (2013) Physical and chemical characterisation of PM emissions from two ships operating in European Emission Control Areas. Atmos Meas Tech 6:3577–3596
Mueller D, Uibel S, Takemura M, Klingelhoefer D, Groneberg DA (2011) Ships, ports and particulate air pollution - an analysis of recent studies. J Occup Med Toxicol 6:31
Mueller L, Jakobi G, Czech H, Stengel B, Orasche J, Arteaga-Salas JM, Karg E, Elsasser M, Sippula O, Streibel T, Slowik JG, Prevot ASH, Jokiniemi J, Rabe R, Harndorf H, Michalke B, Schnelle-Kreis J, Zimmermann R (2015) Characteristics and temporal evolution of particulate emissions from a ship diesel engine. Appl Energy 155:204–217
Nakatsubo R, Oshita Y, Aikawa M, Takimoto M, Kubo T, Matsumura C, Takaishi Y, Hiraki T (2020) Influence of marine vessel emissions on the atmospheric PM2.5 in Japan’s around the congested sea areas. Sci Total Environ 702:134744
Peng Y, Suzuki M, Nguyen LK, Zhang X, Aikawa M (2021) Presence and source attribution of airborne anthropogenic/non-sea-salt inorganic chloride determined by filter-pack method at eastern edge in East Asia. Water Air Soil Pollut 232:238
Solakivi T, Laari S, Kiiski T, Töyli J, Ojala L (2019) How shipowners have adapted to sulphur regulations – evidence from Finnish seaborne trade. Case Stud Transp Policy 7:338–345
Van TC, Ramirez J, Rainey T, Ristovski Z, Brown RJ (2019) Global impacts of recent IMO regulations on marine fuel oil refining processes and ship emissions. Transp Res D: Transp Environ 70:123–134
Viana M, Rizza V, Tobías A, Carr E, Corbett J, Sofiev M, Karanasiou A, Buonanno G, Fann N (2020) Estimated health impacts from maritime transport in the Mediterranean region and benefits from the use of cleaner fuels. Environ Int 138:105670
Wang X, Yi W, Lv Z, Deng F, Zheng S, Xu H, Zhao J, Liu H, He K (2021) Ship emissions around China under gradually promoted control policies from 2016 to 2019. Atmos Chem Phys 21:13835–13853
Wen J, Wang X, Zhang Y, Zhu H, Chen Q, Tian Y, Shi X, Shi G, Feng Y (2018) PM2.5 source profiles and relative heavy metal risk of ship emissions: source samples from diverse ships, engines, and navigation processes. Atmos Environ 191:55–63
Winebrake JJ, Corbett JJ, Green EH, Lauer A, Eyring V (2009) Mitigating the health impacts of pollution from oceangoing shipping: an assessment of low-sulfur fuel mandates. Environ Sci Technol 43:4776–4782
Winnes H, Fridell E, Moldanová J (2020) Effects of marine exhaust gas scrubbers on gas and particle emissions. J Mar Sci Eng 8:299
Wu SP, Li X, Xiao SH, Zhang J, Schwab JJ (2022) Solubility of aerosol minor and trace elements in Xiamen Island, Southeast China: size distribution, health risk and dry deposition. Sci Total Environ 844:157100
Zhang X, Aikawa M (2023) The variation of PM2.5 from ship emission under low-sulfur regulation: a case study in the coastal suburbs of Kitakyushu Japan. Sci Total Environ 858:159968
Zhang X, Zhang K, Lv W, Liu B, Aikawa M, Wang J (2019) Characteristics and risk assessments of heavy metals in fine and coarse particles in an industrial area of central China. Ecotoxicol Environ Saf 179:1–8
Zhang X, Eto Y, Aikawa M (2021a) Risk assessment and management of PM2.5-bound heavy metals in the urban area of Kitakyushu, Japan. Sci Total Environ 795:148748
Zhang X, Murakami T, Wang J, Aikawa M (2021b) Sources, species and secondary formation of atmospheric aerosols and gaseous precursors in the suburb of Kitakyushu, Japan. Sci Total Environ 763:143001
Zhang X, Sun M, Aikawa M (2023) Characteristics of PM2.5-bound metals in Japan over six years: Spatial distribution, health risk, and source analysis. J Environ Manag 344:118750
Zhang X, Murakami T, Wang J, Aikawa M (2024) Unexpected/contrary behavior of aerosol mass concentration in response to the individual components’ concentration reduction in Kitakyushu, Japan. J Environ Sci 135:630–639
Zhao M, Zhang Y, Ma W, Fu Q, Yang X, Li C, Zhou B, Yu Q, Chen L (2013) Characteristics and ship traffic source identification of air pollutants in China’s largest port. Atmos Environ 64:277–286
Zhi M, Zhang X, Zhang K, Ussher SJ, Lv W, Li J, Gao J, Luo Y, Meng F (2021) The characteristics of atmospheric particles and metal elements during winter in Beijing: size distribution, source analysis, and environmental risk assessment. Ecotoxicol Environ Saf 211:111937
Zhu M, Li KX, Lin KC, Shi W, Yang J (2020) How can shipowners comply with the 2020 global sulphur limit economically? Transp Res D: Transp Environ 79:102234
Zou Z, Zhao J, Zhang C, Zhang Y, Yang X, Chen J, Xu J, Xue R, Zhou B (2020) Effects of cleaner ship fuels on air quality and implications for future policy: a case study of Chongming Ecological Island in China. J Clean Prod 267:122088
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XZ: conceptualization, statistical analysis, model simulation, writing—original draft, writing—review and editing, visualization; MA: project administration, funding acquisition, supervision, conceptualization, methodology, writing—review and editing, visualization, resources.
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Zhang, X., Aikawa, M. Health risks and air quality by PM2.5 in the leeward area of the Asian continent in the preceding year of the MARPOL Treaty enforcement. Air Qual Atmos Health (2024). https://doi.org/10.1007/s11869-024-01514-5
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DOI: https://doi.org/10.1007/s11869-024-01514-5