Unveiling the drivers of atmospheric methane variability in Iran: A 20-year exploration using spatiotemporal modeling and machine learning

Q2 Environmental Science Environmental Challenges Pub Date : 2024-04-01 DOI:10.1016/j.envc.2024.100946
Seyed Mohsen Mousavi , Naghmeh Mobarghaee Dinan , Saeed Ansarifard , Faezeh Borhani , Asef Darvishi , Farhan Mustafa , Amir Naghibi
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Abstract

Understanding the factors controlling spatial and temporal variability of atmospheric methane concentration (XCH4) is crucial for mitigating its impacts and implementing emission reduction strategies. This study comprehensively investigates XCH4 and its driving factors (environmental, meteorological, and anthropogenic activity) across Iran over 20 years, from 2003 to 2022. It combines multi-source satellite observations, advanced spatiotemporal modeling techniques, correlation analysis, and machine learning algorithms. The spatiotemporal analysis showed notable spatial variation, with high XCH4 levels in central, southern, and eastern Iran and lower levels in the northwest and north. Moreover, distinct seasonal cycles emerged, with maximum XCH4 occurring during summer (August-September) and minimum levels in spring (April-May). Correlation analysis and variable importance assessment were developed to elucidate the key drivers governing XCH4 dynamics. Correlation analysis revealed that vegetation cover, precipitation, and soil moisture were negatively correlated with XCH4, while temperature indices showed a positive correlation, exhibiting the highest correlation in time dispersion and quantity among the studied variables. The Permutation Importance technique, used with a Random Forest classifier, a machine learning-based approach that considers the role of all variables together, showed that land surface temperature, wind speed, soil moisture, and vegetation cover are the dominant controls, with their importance ranked respectively. Surprisingly, anthropogenic emissions played a relatively minor role in shaping XCH4 distributions at the regional scale. These findings highlight the significant influence of meteorological variables and ecosystem processes on XCH4 modulation, revealing intricate Earth system feedbacks that inform targeted mitigation strategies and predictive models for curbing greenhouse gas emissions and mitigating climate change impacts.

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揭示伊朗大气甲烷变化的驱动因素:利用时空建模和机器学习进行 20 年探索
了解控制大气甲烷浓度(XCH4)时空变化的因素对于减轻其影响和实施减排战略至关重要。本研究全面调查了 2003 年至 2022 年 20 年间伊朗各地的 XCH4 及其驱动因素(环境、气象和人为活动)。研究结合了多源卫星观测、先进的时空建模技术、相关性分析和机器学习算法。时空分析显示出明显的空间差异,伊朗中部、南部和东部的 XCH4 水平较高,而西北部和北部的水平较低。此外,还出现了明显的季节性周期,XCH4 的最高水平出现在夏季(8 月至 9 月),最低水平出现在春季(4 月至 5 月)。相关分析和变量重要性评估旨在阐明 XCH4 动态变化的主要驱动因素。相关性分析表明,植被覆盖、降水和土壤水分与 XCH4 呈负相关,而温度指数则呈正相关,在所研究的变量中,温度指数在时间分散性和数量上的相关性最高。随机森林分类器是一种基于机器学习的方法,可综合考虑所有变量的作用,该分类器使用的排列重要性技术表明,地表温度、风速、土壤水分和植被覆盖是最主要的控制因素,其重要性依次排列。令人惊讶的是,人为排放在区域尺度上对 XCH4 分布的影响相对较小。这些发现凸显了气象变量和生态系统过程对 XCH4 调节的重要影响,揭示了错综复杂的地球系统反馈,为有针对性的减缓战略和预测模型提供了信息,以遏制温室气体排放并减轻气候变化的影响。
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来源期刊
Environmental Challenges
Environmental Challenges Environmental Science-Environmental Engineering
CiteScore
8.00
自引率
0.00%
发文量
249
审稿时长
8 weeks
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