资源环境科技发展态势分析平台

Due to urbanization and industrialization, PM_2.5 (particulate matter with a diameter less than 2.5 μm) pollution has become a serious environmental problem. The low spatial resolution and insufficient coverage of PM_2.5 observation stations affect research on pollution causes and human health risks. With the launch of FY-4A, new generation of Chinese geostationary weather satellites, it is possible to obtain PM_2.5 with high temporal and spatial resolution covering all China. In this study, FY-4A top-of-the-atmosphere reflectance data, meteorological factors, and geographic information were input into the deep forest (DF) model to obtain the hourly PM_2.5 in China. The samples based 10-fold cross validation of DF with an hourly R² of 0.83–0.88, and the root mean square error is 8.81–14.7 μg/m³, while the R² of the 10-fold cross validation result based on sites was 0.77. The monthly (R² = 0.98) and seasonal (R² = 0.99) estimated results showed high consistency with the observations. Feature importance showed that the contribution of estimated features to the model varies with regions and seasons. Estimation results indicated the substantial spatiotemporal differences in PM_2.5, and pollution was the highest between 09:00–10:00 and then gradually decreased. Regions with highest pollution of PM_2.5 in China were mainly distributed in the Tarim Basin and Central China. The pollution assessment results in China indicated that: 1) In more than 80% of the winter days PM_2.5 was higher than the World Health Organization interim target 3 (37.5 μg/m³); 2) The bimodal distribution of PM_2.5 indicated that there are obvious differences in pollution between cities and suburbs; 3) In autumn and winter, the regions where population-weighted PM_2.5 was higher than IT-3 were mainly in Beijing-Tianjin-Hebei, Central China, Guanzhong Plain, Sichuan Basin, and Yangtze River Delta. Our results showed that FY-4A has advantages of high resolution and coverage and thus shows great potential for estimating pollutants.