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Improving air quality assessment using physics-inspired deep graph learning
Environmental Studies and Forestrynpj Climate and Atmospheric Science

Improving air quality assessment using physics-inspired deep graph learning

L. Li, J. Wang, et al.

Discover a groundbreaking approach to air quality assessment developed by Lianfa Li and colleagues. Their innovative hybrid multilevel graph neural network incorporates fluid physics to significantly enhance the reliability of air pollutant predictions in China, achieving a remarkable improvement in accuracy and consistency.... show more
GeneralSummaryMetrics
Abstract
Existing methods for fine-scale air quality assessment have significant gaps in their reliability. Purely data-driven methods lack any physically-based mechanisms to simulate the interactive process of air pollution, potentially leading to physically inconsistent or implausible results. Here, we report a hybrid multilevel graph neural network that encodes fluid physics to capture spatial and temporal dynamic characteristics of air pollutants. On a multi-air pollutant test in China, our method consistently improved extrapolation accuracy by an average of 11–22% compared to several baseline machine learning methods, and generated physically consistent spatiotemporal trends of air pollutants at fine spatial and temporal scales.
Publisher
npj Climate and Atmospheric Science
Published On
Sep 27, 2023
Authors
Lianfa Li, Jinfeng Wang, Meredith Franklin, Qian Yin, Jiajie Wu, Gustau Camps-Valls, Zhiping Zhu, Chengyi Wang, Yong Ge, Markus Reichstein
DOI
https://doi.org/10.1038/s41612-023-00475-3
Tags
air qualityneural networkpollutantsfluid physicsspatiotemporal trends
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