Improved seamless mapping of surface O3 concentrations using an integrated deep learning framework

IF 8.5 1区地球科学 Q1 METEOROLOGY & ATMOSPHERIC SCIENCES

npj Climate and Atmospheric Science Pub Date : 2025-03-28 DOI:10.1038/s41612-025-01007-x

Tongwen Li, Jingan Wu, Yuan Wang, Yuenong Su

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引用次数: 0

Abstract

Satellite-derived ozone (O₃) data often contain spatial gaps due to factors such as cloud cover. To achieve seamless O₃ mapping, researchers typically either reconstructed the missing satellite input data before the O₃ inversion or reconstructed the missing O₃ data after inversion. Unlike previous step-by-step approaches, this study proposed a deep learning-based “inversion-reconstruction” integrated framework to estimate seamless surface O₃. By inputting gapped satellite data and other auxiliary information, the framework directly yielded gap-free O₃ data. The O₃ inversion and reconstruction results were jointly optimized in the framework, ensuring high consistency in the seamless mapping of O₃ concentrations. Holdout, spatial, and temporal validations demonstrated the effectiveness of our method for mapping seamless O₃ across China in 2019, with R² values of 0.809, 0.760, and 0.733, respectively. Daily seamless mapping revealed the spatiotemporal patterns of O₃, pollution episodes, and their potential transport routes. The satellite-inverted gapped O₃ data showed a 7.37 ± 4.18% difference from the gap-free merged O₃ data on a national daily scale.

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使用集成深度学习框架改进表面O3浓度的无缝映射

卫星生成的臭氧（O3）数据往往由于云层等因素而存在空间缺口。为了实现O3的无缝映射，研究人员通常要么在O3反演前重建缺失的卫星输入数据，要么在反演后重建缺失的O3数据。与之前的逐步方法不同，本研究提出了一种基于深度学习的“反演-重建”集成框架来估计无缝表面O3。通过输入有缺口的卫星数据和其他辅助信息，该框架直接生成无缺口的O3数据。在框架内对O3反演和重建结果进行了联合优化，保证了O3浓度无缝映射的高一致性。结果表明，该方法对2019年中国无缝O3进行了有效映射，R²值分别为0.809、0.760和0.733。每日无缝映射揭示了O3的时空格局、污染事件及其潜在的运输路线。卫星反演的缺口O3数据与无缺口合并O3数据在全国日尺度上的差异为7.37±4.18%。

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来源期刊

npj Climate and Atmospheric Science Earth and Planetary Sciences-Atmospheric Science

CiteScore

8.80

自引率

3.30%

发文量

审稿时长

21 weeks

期刊介绍： npj Climate and Atmospheric Science is an open-access journal encompassing the relevant physical, chemical, and biological aspects of atmospheric and climate science. The journal places particular emphasis on regional studies that unveil new insights into specific localities, including examinations of local atmospheric composition, such as aerosols. The range of topics covered by the journal includes climate dynamics, climate variability, weather and climate prediction, climate change, ocean dynamics, weather extremes, air pollution, atmospheric chemistry (including aerosols), the hydrological cycle, and atmosphere–ocean and atmosphere–land interactions. The journal welcomes studies employing a diverse array of methods, including numerical and statistical modeling, the development and application of in situ observational techniques, remote sensing, and the development or evaluation of new reanalyses.