In China, ozone pollution shows an increasing trend and becomes the primary air pollutant in warm seasons. Leveraging the air quality monitoring network, a random forest model is developed to predict the daily maximum 8-h average ozone concentrations ([O-3](MDA8)) across China in 2015 for human exposure assessment. This model captures the observed spatiotemporal variations of [O-3](MDA8) by using the data of meteorology, elevation, and recent-year emission inventories (cross-validation R-2 = 0.69 and RMSE = 26 mu g/m(3)). Compared with chemical transport models that require a plenty of variables and expensive computation, the random forest model shows comparable or higher predictive performance based on only a handful of readily-available variables at much lower computational cost. The nationwide population-weighted [O-3](MDA8) is predicted to be 84 23 mu g/m(3) annually, with the highest seasonal mean in the summer (103 +/- 8 mu g/m(3)). The summer [O-3](MDA8) is predicted to be the highest in North China (125 +/- 17 mu g/m(3)). Approximately 58% of the population lives in areas with more than 100 nonattainment days ([O-3](MDA8)>100 mu g/m(3)), and 12% of the population are exposed to [O-3](MDA8)>160 mu g/m(3) (WHO Interim Target 1) for more than 30 days. As the most populous zones in China, the Beijing-Tianjin Metro, Yangtze River Delta, Pearl River Delta, and Sichuan Basin are predicted to be at 154, 141, 124, and 98 nonattainment days, respectively. Effective controls of 03 pollution are urgently needed for the highly populated zones, especially the Beijing-Tianjin Metro with seasonal [O-3](MDA8) of 140 +/- 29 mu g/m(3) in summer. To the best of the authors' knowledge, this study is the first statistical modeling work of ambient O-3 for China at the national level. This timely and extensively validated [O-3](MDA8) dataset is valuable for refining epidemiological analyses on O-3 pollution in China.

• 出版日期2018-2
• 单位四川大学; 浙江省农业科学院