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Critical Role of Secondary Organic Aerosol in Urban Atmospheric Visibility Improvement Identified by Machine Learning

Xing Peng, Tingting Xie, Meng‐Xue Tang, Yong Cheng, Yan Peng, Fenghua Wei, Li‐Ming Cao, Kuangyou Yu, Ke Du, Ling‐Yan He, Xiaofeng Huang

2023Environmental Science & Technology Letters48 citationsDOI

Abstract

Understanding the relationship between atmospheric visibility and aerosol emission sources and identifying the key drivers of visibility have significant implications for the radiative forcing of aerosol. In this work, we combined the positive matrix factorization (PMF) model and machine learning (ML) models (the extreme gradient boosting model (XGBoost) and the Shapely additive explanations model (SHAP)) to identify the key drivers of visibility improvement based on long-term observations of visibility and PM 2.5 composition in Shenzhen, China. From 2014 to 2021, the annual average levels of visibility increased from 17.2 to 27.0 km, which is tightly associated with the decreasing year by year PM 2.5 concentrations. ML models, with distinct advantages in dealing with nonlinear relationships, revealed that secondary organic aerosol (SOA) is the major driver determining visibility, which is inconsistent with inorganic salts being the major driver identified by the widely used traditional linear method. Visibility improvement in Shenzhen was also found primarily driven by a decrease in SOA, highlighting that SOA in PM 2.5 plays a critical role in radiative balance. This is the first study to investigate source impacts on atmospheric visibility using novel ML models, reflecting the great potential of ML methods in air pollution data analysis.

Topics & Concepts

VisibilityAerosolEnvironmental scienceMeteorologyRadiative transferAtmospheric sciencesRadiative forcingComputer scienceGeographyPhysicsOpticsAir Quality and Health ImpactsAtmospheric chemistry and aerosolsAir Quality Monitoring and Forecasting
Critical Role of Secondary Organic Aerosol in Urban Atmospheric Visibility Improvement Identified by Machine Learning | Litcius