A deep learning model for predicting daily PM2.5 concentration in response to emission reduction.
Journal:
Science advances
Published Date:
Jul 17, 2026
Abstract
Air pollution remains a leading global health threat, with fine particulate matters (PM2.5) causing millions of premature deaths annually. Chemical transport models (CTMs) are essential for estimating how emission controls improve air quality but are computationally intensive. Here, we present CleanAir, a deep learning model that simulates daily PM2.5 concentration and its chemical composition in response to emission reductions at a 36-kilometer horizontal resolution. Built on a residual symmetric three-dimensional U-Net architecture, CleanAir can estimate 365-day PM2.5 concentration over China within 10 seconds on a graphics processing unit or 160 seconds on a central processing unit-three to four orders of magnitude faster than CTMs. Results from CleanAir agree well with those from a Community Multiscale Air Quality (CMAQ) model for both PM2.5 concentration and emission-induced changes. Trained on 2416 emission scenarios from the CMAQ model, CleanAir generalizes well across unseen meteorology and emissions. With fast simulation capability, CleanAir enables extensive evaluation for short-term emission control measures and long-term mitigation pathways, leading to more responsive decision-making.
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