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Technical Papers

Influence of fossil-fuel power plant emissions on the surface fine particulate matter in the Seoul Capital Area, South Korea

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Pages 863-873 | Received 16 Dec 2015, Accepted 25 Mar 2016, Published online: 07 Jul 2016
 

ABSTRACT

The South Korean government plans to reduce region-wide annual PM2.5 (particulate matter with an aerodynamic diameter ≤2.5 μm) concentrations in the Seoul Capital Area (SCA) from 2010 levels of 27 µg/m3 to 20 µg/m3 by 2024. At the same time, it is inevitable that emissions from fossil-fuel power plants will continue to increase if electricity generation expands and the generation portfolio remains the same in the future. To estimate incremental PM2.5 contributions due to projected electricity generation growth in South Korea, we utilized an ensemble forecasting member of the Integrated Multidimensional Air Quality System for Korea based on the Community Multi-scale Air Quality model. We performed sensitivity runs with across-the-board emission reductions for all fossil-fuel power plants in South Korea to estimate the contribution of PM2.5 from domestic fossil-fuel power plants. We estimated that fossil-fuel power plants are responsible for 2.4% of the annual PM2.5 national ambient air quality standard in the SCA as of 2010. Based on the electricity generation and the annual contribution of fossil-fuel power plants in 2010, we estimated that annual PM2.5 concentrations may increase by 0.2 µg/m3 per 100 TWhr due to additional electricity generation. With currently available information on future electricity demands, we estimated that the total future contribution of fossil-fuel power plants would be 0.87 µg/m3, which is 12.4% of the target reduction amount of the annual PM2.5 concentration by 2024. We also approximated that the number of premature deaths caused by existing fossil-fuel power plants would be 736 in 2024. Since the proximity of power plants to the SCA and the types of fuel used significantly impact this estimation, further studies are warranted on the impact of physical parameters of plants, such as location and stack height, on PM2.5 concentrations in the SCA due to each precursor.

Implications: Improving air quality by reducing fine particle pollution is challenging when fossil-fuel-based electricity production is increasing. We show that an air quality forecasting system based on a photochemical model can be utilized to efficiently estimate PM2.5 contributions from and health impacts of domestic power plants. We derived PM2.5 concentrations per unit amount of electricity production from existing fossil-fuel power plants in South Korea. We assessed the health impacts of existing fossil-fuel power plants and the PM2.5 concentrations per unit electricity production to quantify the significance of existing and future fossil-fuel power plants with respect to the planned PM2.5 reduction target.

Funding

The authors would like to thank the Korea Ministry of Environment and the PM2.5 Research Center, supported by the Ministry of Science, ICT, and Future Planning, and the National Research Foundation of Korea (2014M3C8A5030624) for their support.

Additional information

Funding

The authors would like to thank the Korea Ministry of Environment and the PM2.5 Research Center, supported by the Ministry of Science, ICT, and Future Planning, and the National Research Foundation of Korea (2014M3C8A5030624) for their support.

Notes on contributors

Byeong-Uk Kim

Byeong-Uk Kim is an environmental modeler at the Georgia Environmental Protection Division, Atlanta, GA.

Okgil Kim

Okgil Kim is a graduate student in the Department of Environmental Engineering, Ajou University, Suwon, South Korea.

Hyun Cheol Kim

Hyun Cheol Kim is a research scientist at the NOAA/Air Resources Laboratory, College Park, MD, and UMD/Cooperative Institute for Climate and Satellites, College Park, MD.

Soontae Kim

Soontae Kim is an associate professor in the Department of Environmental Engineering, Ajou University, Suwon, South Korea.

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