利用机器学习评估COVID-19对中国上空卫星观测气溶胶负荷的影响

H. Andersen, J. Cermak, Roland Stirnberg, J. Fuchs, Miae Kim, E. Pauli
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引用次数: 4

摘要

气溶胶是气候系统的重要组成部分,对人类健康构成威胁。在这里,对冠状病毒爆发的封锁反应被用来分析人为气溶胶源急剧减少对卫星反演气溶胶光学深度(AOD)的影响。应用机器学习模型估计了2020年初中国最初封锁期间的每日AOD。该模型利用气溶胶气候学、地理和气象条件的信息,解释了69%的日常AOD变化。对模型预期的AOD和观测到的AOD的比较表明,在中国的封锁期间,AOD没有明显的、系统的下降。2020年3月,在华北平原部分沿海地区,区域AOD显著低于机器学习模型的预期,并延伸至朝鲜半岛。虽然这可能表明封锁对区域臭氧耗氧量的影响很小,并且可能表明封锁措施的跨界影响,但由于方法的不确定性和有限的样本量,这种臭氧耗氧量的减少不能明确地归因于人为排放的减少。将气候预期的AOD与天气调整后的AOD预期进行比较,表明气象影响在这段时间内显著增加了AOD,这与最近的文献一致。这些发现强调了气溶胶变率的复杂性和基于观测归因柱状气溶胶变化的挑战。
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Assessment of COVID-19 effects on satellite-observed aerosol loading over China with machine learning
Abstract Aerosols are a critical component of the climate system and a risk to human health. Here, the lockdown response to the coronavirus outbreak is used to analyse effects of dramatic reduction in anthropogenic aerosol sources on satellite-retrieved aerosol optical depth (AOD). A machine learning model is applied to estimate daily AOD during the initial lockdown in China in early 2020. The model uses information on aerosol climatology, geography and meteorological conditions, and explains 69% of the day-to-day AOD variability. A comparison of model-expected and observed AOD shows that no clear, systematic decrease in AOD is apparent during the lockdown in China. During March 2020, regional AOD is observed to be significantly lower than expected by the machine learning model in some coastal regions of the North China Plains and extending to the Korean peninsula. While this may possibly indicate a small lockdown effect on regional AOD, and potentially pointing trans-boundary effects of the lockdown measures, due to uncertainties associated with the method and the limited sample sizes, this AOD decrease cannot be unequivocally attributed to reduced anthropogenic emissions. Climatologically expected AOD is compared to a weather-adjusted expectation of AOD, indicating that meteorological influences have acted to significantly increase AOD during this time, in agreement with recent literature. The findings highlight the complexity of aerosol variability and the challenges of observation-based attribution of columnar aerosol changes.
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