Machine Learning-Driven Spatiotemporal Analysis of Ozone Exposure and Health Risks in China

IF 3.8 2区 地球科学 Q2 METEOROLOGY & ATMOSPHERIC SCIENCES
Chendong Ma, Jun Song, Maohao Ran, Zhenglin Wan, Yike Guo, Meng Gao
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Abstract

Accurate and fine-scaled prediction of ozone concentrations across space and time, as well as the assessment of associated human risks, is crucial for protecting public health and promoting environmental conservation. This paper introduces NetGBM, an innovative machine-learning model designed to comprehensively model ozone levels across China's diverse topography and analyze the spatiotemporal distribution of ozone and exposure. Our model focuses on daily, weekly, and monthly predictions, achieving commendable R 2 ${\mathrm{R}}^{2}$ coefficients of 0.83, 0.77, and 0.79, respectively. By constructing a gridded map of ozone and incorporating both land use and meteorological features into each grid, we achieved ozone prediction at a high spatiotemporal resolution, outperforming previous research in terms of performance and scale, particularly in regions with limited monitoring stations. The results can be further improved when applied to regional research using meteorological and ozone data from regional stations. Additionally, our research revealed that temperature is the most significant factor affecting ozone concentrations across China. In health risk assessment, we retrieved a high-resolution spatial distribution of ozone-attributed mortality for 5-COD and daily ozone inhalation distributions during our study period. We concluded that ozone-attributed mortality is predominantly caused by stroke and IHD, accounting for more than 70% of the total deaths in 2021, with the highest mortality rates in developed urban areas such as the NCP and the YRD. Our experiment demonstrated the potential of NetGBM in robustly modeling ozone across China with high spatiotemporal resolution and its applicability in measuring associated health risks.

Abstract Image

机器学习驱动的中国臭氧暴露与健康风险时空分析
对臭氧浓度进行跨时空的精确和精细预测,并评估相关的人类风险,对于保护公众健康和促进环境保护至关重要。本文介绍了一种创新的机器学习模型 NetGBM,该模型旨在全面模拟中国不同地形的臭氧浓度,并分析臭氧和暴露的时空分布。我们的模型侧重于日、周和月预测,R 2 ${mathrm{R}}^{2}$ 系数分别为 0.83、0.77 和 0.79。通过构建臭氧网格图,并将土地利用和气象特征纳入每个网格,我们实现了高时空分辨率的臭氧预测,在性能和规模上都优于以往的研究,尤其是在监测站点有限的地区。在利用区域监测站的气象和臭氧数据进行区域研究时,这些结果还能得到进一步改进。此外,我们的研究还发现,温度是影响中国各地臭氧浓度的最重要因素。在健康风险评估方面,我们检索了高分辨率的 5-COD 臭氧致死率空间分布以及研究期间的每日臭氧吸入分布。我们得出的结论是,臭氧导致的死亡主要由中风和高血压引起,占 2021 年总死亡人数的 70% 以上,其中死亡率最高的是发达城市地区,如北高加索地区和长三角地区。我们的实验证明了 NetGBM 在以高时空分辨率对中国臭氧进行稳健建模方面的潜力及其在测量相关健康风险方面的适用性。
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来源期刊
Journal of Geophysical Research: Atmospheres
Journal of Geophysical Research: Atmospheres Earth and Planetary Sciences-Geophysics
CiteScore
7.30
自引率
11.40%
发文量
684
期刊介绍: JGR: Atmospheres publishes articles that advance and improve understanding of atmospheric properties and processes, including the interaction of the atmosphere with other components of the Earth system.
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