English

Advancing global aerosol forecasting with artificial intelligence

Atmospheric and Oceanic Physics 2024-12-04 v1

Abstract

Aerosol forecasting is essential for air quality warnings, health risk assessment, and climate change mitigation. However, it is more complex than weather forecasting due to the intricate interactions between aerosol physicochemical processes and atmospheric dynamics, resulting in significant uncertainty and high computational costs. Here, we develop an artificial intelligence-driven global aerosol-meteorology forecasting system (AI-GAMFS), which provides reliable 5-day, 3-hourly forecasts of aerosol optical components and surface concentrations at a 0.5{\deg} x 0.625{\deg} resolution. AI-GAMFS combines Vision Transformer and U-Net in a backbone network, robustly capturing the complex aerosol-meteorology interactions via global attention and spatiotemporal encoding. Trained on 42 years of advanced aerosol reanalysis data and initialized with GEOS Forward Processing (GEOS-FP) analyses, AI-GAMFS delivers operational 5-day forecasts in one minute. It outperforms the Copernicus Atmosphere Monitoring Service (CAMS) global forecasting system, GEOS-FP forecasts, and several regional dust forecasting systems in forecasting most aerosol variables including aerosol optical depth and dust components. Our results mark a significant step forward in leveraging AI to refine physics-based aerosol forecasting, facilitating more accurate global warnings for aerosol pollution events, such as dust storms and wildfires.

Keywords

Cite

@article{arxiv.2412.02498,
  title  = {Advancing global aerosol forecasting with artificial intelligence},
  author = {Ke Gui and Xutao Zhang and Huizheng Che and Lei Li and Yu Zheng and Linchang An and Yucong Miao and Hujia Zhao and Oleg Dubovik and Brent Holben and Jun Wang and Pawan Gupta and Elena S. Lind and Carlos Toledano and Hong Wang and Zhili Wang and Yaqiang Wang and Xiaomeng Huang and Kan Dai and Xiangao Xia and Xiaofeng Xu and Xiaoye Zhang},
  journal= {arXiv preprint arXiv:2412.02498},
  year   = {2024}
}

Comments

37 pages, 14 figures

R2 v1 2026-06-28T20:21:28.937Z