Proposal of a methodology for prediction of heavy metals concentration based on PM2.5 concentration and meteorological variables using machine learning
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Published:2024-02-27
Issue:1
Volume:18
Page:
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ISSN:2287-1160
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Container-title:Asian Journal of Atmospheric Environment
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language:en
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Short-container-title:Asian J. Atmos. Environ
Author:
Park Shin-Young, Lee Hye-Won, Kwon Jaymin, Yoon Sung-Won, Lee Cheol-MinORCID
Abstract
AbstractIn this study, we developed a prediction model for heavy metal concentrations using PM2.5 concentrations and meteorological variables. Data was collected from five sites, encompassing meteorological factors, PM2.5, and 18 metals over 2 years. The study employed four analytical methods: multiple linear regression (MLR), random forest regression (RFR), gradient boosting, and artificial neural networks (ANN). RFR was the best predictor for most metals, and gradient boosting and ANN were optimal for certain metals like Al, Cu, As, Mo, Zn, and Cd. Upon evaluating the final model’s predicted values against the actual measurements, differences in the concentration distribution between measurement locations were observed for Mn, Fe, Cu, Ba, and Pb, indicating varying prediction performances among sites. Additionally, Al, As, Cd, and Ba showed significant differences in prediction performance across seasons. The developed model is expected to overcome the technical limitations involved in measuring and analyzing heavy metal concentrations. It could further be utilized to obtain fundamental data for studying the health effects of exposure to hazardous substances such as heavy metals.
Funder
Korea Environmental Industry and Technology Institute Ministry of Environment
Publisher
Springer Science and Business Media LLC
Reference54 articles.
1. Abbasi, M., Safari, E., Baghdadi, M., & Janmohammadi, M. (2021). Enhanced adsorption of heavy metals in groundwater using sand columns enriched with graphene oxide: Lab-scale experiments and process modeling. Journal of Water Process Engineeing, 40, 101961. 2. Abdullah, S., Nasir, N. .H. .A., Ismail, M., Ahmed, A. .N., & Jarkoni, M. .N. .K. (2019). Development of ozone prediction model in urban area. International Journal of Innovative Technology and Exploring Engineering, 8(10), 2263–2267. https://doi.org/10.35940/ijitee.J1127.0881019 3. Abuduwaili, J., Zhang, Z. Y., & Jiang, F. Q. (2015). Assessment of the distribution, sources and potential ecological risk of heavy metals in the dry surface sediment of Aibi Lake in Northwest China. PLoS ONE, 10(3), e0120001. https://doi.org/10.1371/journal.pone.0120001 4. Almeida, T. S., Sant, M. O., Cruz, J. M., Tormen, L., Bascuñan, V. L. A. F., Azevedo, P. A., Garcia, C. A. B., Alves, J. P., & Araujo, R. G. (2017). Characterisation and source identification of the total airborne particulate matter collected in an urban area of Aracaju, Northeast. Brazil. Environmental Pollution., 226, 444–451. https://doi.org/10.1016/j.envpol.2017.04.018 5. Atiemo, M. S., Ofosu, G. F., Kuranchie-Mensah, H., Tutu, A. O., Palm, N. D., & Blankson, S. A. (2011). Contamination assessment of heavy metals in road dust from selected roads in Accra, Ghana. Research Journal of Environmental and Earth Sciences, 3(5), 473–480.
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