Aerosol classification under non-clear sky conditions based on geostationary satellite FY-4A and machine learning models

IF 4.2 2区环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES

Atmospheric Environment Pub Date : 2024-10-24 DOI:10.1016/j.atmosenv.2024.120891

Bin Chen , Qia Ye , Xingzhao Zhou , Zhihao Song , Yuxiang Ren

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引用次数: 0

Abstract

Accurately identifying and classifying aerosols is a key to understanding their sources, assessing their chemical and physical changes, and comprehending their feedback mechanisms within climate system. However, existing aerosol classification methods have two limitations: First, ground remote sensing products have limited spatial coverage, and polar orbit satellite data suffer from low temporal resolution. Second, satellite-based aerosol classification methods are affected by cloud interference, resulting in data gaps. To overcome these challenges, this study utilized the extreme tree algorithm (ET) and integrated the FY-4A TOAR dataset with meteorological and geographical information, using a sequential forward selection method for optimal input feature selection. Focusing on the Asian region (70–140°E, 15–55°N), three models were used to generate hourly aerosol classification products: the Clear air-Cloud-Aerosol-Mixed cloud and aerosol (CCAM-ET) model, the Dust-Polluted dust-Other aerosols-Mixed aerosols (DPOM-ET) model under clear sky conditions, and the DPOM-ET model under non-clear sky conditions. The evaluated accuracy of the CCAM-ET model was 85%, demonstrating its effectiveness in identifying cloud and aerosol under various conditions. The CCAM model can achieve an accuracy of 78% when aerosols are located above clouds and 59% when they are below clouds. The DPOM-ET model achieved an evaluation accuracy of 89% for clear sky areas and 87% for non-clear sky areas, respectively, and was superior to traditional methods. Long-term data indicated a significant correlation between the distributions of different types of aerosols and human activity. Polluted dust is common in southwest China during spring and in northern China during winter. Additionally, from 2018 to 2020, dust occurrences decreased on the Indian Peninsula, while non-dust aerosols increased significantly in India and Southeast Asia.

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基于地球静止卫星 FY-4A 和机器学习模型的非晴空条件下的气溶胶分类

准确识别和分类气溶胶是了解其来源、评估其化学和物理变化以及理解其在气候系统中的反馈机制的关键。然而，现有的气溶胶分类方法有两个局限性：首先，地面遥感产品的空间覆盖范围有限，极轨卫星数据的时间分辨率较低。其次，基于卫星的气溶胶分类方法受云层干扰的影响，导致数据缺失。为了克服这些挑战，本研究利用极端树算法（ET），将 FY-4A TOAR 数据集与气象和地理信息整合在一起，采用顺序前向选择法进行最佳输入特征选择。以亚洲地区（70-140°E，15-55°N）为重点，使用三种模型生成每小时气溶胶分类产品：晴空-云-气溶胶-混合云和气溶胶（CCAM-ET）模型、晴空条件下的粉尘-污染粉尘-其他气溶胶-混合气溶胶（DPOM-ET）模型和非晴空条件下的 DPOM-ET 模型。经评估，CCAM-ET 模型的准确率为 85%，证明了其在各种条件下识别云和气溶胶的有效性。当气溶胶位于云层之上时，CCAM 模型的准确率为 78%，当气溶胶位于云层之下时，准确率为 59%。DPOM-ET 模型在晴朗天空区域和非晴朗天空区域的评估准确率分别达到 89% 和 87%，优于传统方法。长期数据表明，不同类型气溶胶的分布与人类活动之间存在明显的相关性。污染性沙尘在中国西南地区的春季和北方地区的冬季很常见。此外，从2018年到2020年，印度半岛的沙尘发生率有所下降，而印度和东南亚的非沙尘气溶胶则显著增加。

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来源期刊

Atmospheric Environment 环境科学-环境科学

CiteScore

9.40

自引率

8.00%

发文量

458

审稿时长

53 days

期刊介绍： Atmospheric Environment has an open access mirror journal Atmospheric Environment: X, sharing the same aims and scope, editorial team, submission system and rigorous peer review. Atmospheric Environment is the international journal for scientists in different disciplines related to atmospheric composition and its impacts. The journal publishes scientific articles with atmospheric relevance of emissions and depositions of gaseous and particulate compounds, chemical processes and physical effects in the atmosphere, as well as impacts of the changing atmospheric composition on human health, air quality, climate change, and ecosystems.