Urban–Rural Disparities in Air Quality Responses to Traffic Changes in a Megacity of China Revealed Using Machine Learning

Wen, Yifan; Zhou, Zhi-Yuan; Zhang, Shaojun; Wallington, Timothy J.; Shen, Weijian; Tan, Qinwen; Deng, Ye; Wu, Ye

doi:10.1021/acs.estlett.2c00246

Cited by 10 publications

(7 citation statements)

References 33 publications

(77 reference statements)

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“…The Agrimonia dataset could be useful to other researchers, for example, in comparing urban air pollution and rural air quality 7 , 8 . Other uses of the dataset may move toward the study of different livestock management techniques and organic products 9 or for epidemiological studies, which aim to assess the impact of agricultural emissions on the mortality attributable to air pollution 10 .…”

Section: Background and Summarymentioning

confidence: 99%

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

et al. 2023

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The air in the Lombardy region, Italy, is one of the most polluted in Europe because of limited air circulation and high emission levels. There is a large scientific consensus that the agricultural sector has a significant impact on air quality. To support studies quantifying the role of the agricultural and livestock sectors on the Lombardy air quality, this paper presents a harmonised dataset containing daily values of air quality, weather, emissions, livestock, and land and soil use in the years 2016–2021, for the Lombardy region. The daily scale is obtained by averaging hourly data and interpolating other variables. In fact, the pollutant data come from the European Environmental Agency and the Lombardy Regional Environment Protection Agency, weather and emissions data from the European Copernicus programme, livestock data from the Italian zootechnical registry, and land and soil use data from the CORINE Land Cover project. The resulting dataset is designed to be used as is by those using air quality data for research.

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Section: Background and Summarymentioning

confidence: 99%

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

et al. 2023

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“…However, most of these methods are insufficient to address the dynamic and fine-scale traffic-induced air pollution patterns as they typically consider static geo-features (e.g., road length) in their frameworks . On-road traffic is recognized as one of the most important contributors to urban air pollution such as NO 2 and PM 2.5 , and a major source of exposure disparities in global megacities. ,, Racial/ethnic minorities and lower-income groups were reported to bear a higher risk of exposure to traffic-related air pollution in the U.S., , especially for those living close to busy freight corridors or ports . Moreover, the spatial heterogeneity and temporal dynamics of on-road traffic activities significantly contribute to the complexity of multiscale and time-varying air quality patterns in megacities.…”

Section: Introductionmentioning

confidence: 99%

“…2 Air pollution in metropolitan areas varies in complex patterns with multiple gradients, including city-level, urban-rural, and neighborhood-level disparities, as well as highly localized and dynamic spikes near major sources. 9 Fine-scale and continuous air quality mapping is thus required to characterize air pollution exposure patterns among residents, identify highly polluted areas and periods, and take targeted actions to combat inequalities through policies. 8 However, the full complexity of multiscale and time-varying air quality patterns in megacities is hard to track despite great advances in air quality measurements and modeling over the past few decades.…”

Section: ■ Introductionmentioning

confidence: 99%

Dynamic Traffic Data in Machine-Learning Air Quality Mapping Improves Environmental Justice Assessment

Wen,

Zhang,

Wang

et al. 2024

Environ. Sci. Technol.

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Air pollution poses a critical public health threat around many megacities but in an uneven manner. Conventional models are limited to depict the highly spatial-and timevarying patterns of ambient pollutant exposures at the community scale for megacities. Here, we developed a machine-learning approach that leverages the dynamic traffic profiles to continuously estimate community-level year-long air pollutant concentrations in Los Angeles, U.S. We found the introduction of real-world dynamic traffic data significantly improved the spatial fidelity of nitrogen dioxide (NO 2 ), maximum daily 8-h average ozone (MDA8 O 3 ), and fine particulate matter (PM 2.5 ) simulations by 47%, 4%, and 15%, respectively. We successfully captured PM 2.5 levels exceeding limits due to heavy traffic activities and providing an "out-oflimit map" tool to identify exposure disparities within highly polluted communities. In contrast, the model without real-world dynamic traffic data lacks the ability to capture the traffic-induced exposure disparities and significantly underestimate residents' exposure to PM 2.5 . The underestimations are more severe for disadvantaged communities such as black and low-income groups, showing the significance of incorporating real-time traffic data in exposure disparity assessment.

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“…Machine learning (ML) models have been demonstrated to be a powerful tool for reconstructing, simulating, and predicting atmospheric pollution, including PM 2.5 , − O 3 , , NO x , , etc., outperforming finely designed chemical transport models . The use of ML models provides greater flexibility and efficiency when utilizing real-world data and is especially adept at revealing complex and hidden nonlinear correlations , that might not be easily identified using traditional physical models, providing new insights into the underlying mechanisms of the studied phenomena .…”

Section: Introductionmentioning

confidence: 99%

“…The SHapley Additive exPlanations (SHAP) framework, for instance, offers insights into the impact of a feature on model outcomes . ML models combined with explainable tools have been extensively used in various aspects of air pollution modeling, ,,, yet their application in reproducing variations in O 2 concentrations, particularly in urban settings, has been rather scant.…”

Section: Introductionmentioning

confidence: 99%

Revealing the Covariation of Atmospheric O₂ and Pollutants in an Industrial Metropolis by Explainable Machine Learning

Liu,

Wang,

Huang

et al. 2023

Environ. Sci. Technol. Lett.

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In urban areas, atmospheric O 2 actively participates in the process of anthropogenic emissions and energy consumption. However, the covariation between atmospheric O 2 and the emitted pollutants has yet to be thoroughly explored. This study examines the covariations between atmospheric O 2 and pollutants in Lanzhou, a semi-arid industrial metropolis. A machine learning (ML)-based O 2 simulator coupled with a SHapley Additive exPlanation (SHAP) algorithm is established to explore and interpret their covariations under diverse conditions. Our findings indicate an increase of 16.3 ppm in the O 2 concentration associated with the atmospheric transport of natural dust particles during dusty weather events. This suggests that natural dust transport can mitigate the depletion of atmospheric O 2 caused by primary emissions and secondary formation of anthropogenic particulate matter. Furthermore, we identify a nonlinear relationship between the concentrations of O 2 and pollutant concentrations, which likely arises from their distinct diffusive abilities. The study highlights the unique pollution characteristics in a semi-arid urban downtown and demonstrates the ability of ML-based methodology to reproduce and interpret the environmental and anthropogenic impacts on the local carbon−oxygen balance.

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Urban–Rural Disparities in Air Quality Responses to Traffic Changes in a Megacity of China Revealed Using Machine Learning

Cited by 10 publications

References 33 publications

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

Dynamic Traffic Data in Machine-Learning Air Quality Mapping Improves Environmental Justice Assessment

Revealing the Covariation of Atmospheric O₂ and Pollutants in an Industrial Metropolis by Explainable Machine Learning

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Urban–Rural Disparities in Air Quality Responses to Traffic Changes in a Megacity of China Revealed Using Machine Learning

Cited by 10 publications

References 33 publications

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

Agrimonia: a dataset on livestock, meteorology and air quality in the Lombardy region, Italy

Dynamic Traffic Data in Machine-Learning Air Quality Mapping Improves Environmental Justice Assessment

Revealing the Covariation of Atmospheric O2 and Pollutants in an Industrial Metropolis by Explainable Machine Learning

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Revealing the Covariation of Atmospheric O₂ and Pollutants in an Industrial Metropolis by Explainable Machine Learning