Machine learning combined with the PMF model reveal the synergistic effects of sources and meteorological factors on PM 2.5 pollution

Machine learning combined with the PMF model reveal the synergistic effects of sources and meteorological factors on PM 2.5 pollution

PM pollution is a complex process mainly affected by emission sources and meteorological conditions. However, it is hard to accurately assess the effects of emission sources and meteorological conditions on the variation of PM concentrations in the complex atmospheric environment. In this study, the...

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Bibliographic Details
Published in:Environmental research Vol. 212; no. Pt B; p. 113322
Main Authors: Zhang, Zhongcheng, Xu, Bo, Xu, Weiman, Wang, Feng, Gao, Jie, Li, Yue, Li, Mei, Feng, Yinchang, Shi, Guoliang
Format: Journal Article
Language:English
Published: Netherlands 21-04-2022
Subjects:
Machine learning
PMF
PM(2.5)
Random forest
Secondary nitrate
Online Access:Get full text
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Summary:PM pollution is a complex process mainly affected by emission sources and meteorological conditions. However, it is hard to accurately assess the effects of emission sources and meteorological conditions on the variation of PM concentrations in the complex atmospheric environment. In this study, the Random Forest model with Shapley Additive exPlanations (RF-SHAP) and Partial Dependence Plot (RF-PDP) was combined with Positive Matrix Factorization (PMF) to evaluate the impacts of various factors on PM pollution. The results show that anthropogenic emissions and meteorological conditions contributed about 67% (40.5 μg/m ) and 33% (19.7 μg/m ) to variation in PM concentrations, respectively. Specifically, secondary nitrate (SN) had the greatest impact among all sources (about 45%). Hence, we further explore the impacts of the primary sources and meteorological conditions on SN formation. Coal combustion and vehicle emissions significantly contribute to the formation of SN by providing a large number of precursor NO . Additionally, the RF-PDP method was further employed to estimate the synergistic effects of primary sources and meteorological conditions on SN formation. The results help reveal strategies to simultaneously reduce SN by controlling primary emissions under suitable meteorological conditions. This work also suggests that the machine learning model can utilize online datasets well and provide a reliable approach for analyzing the causes of PM pollution.
ISSN:1096-0953