Integrated Analysis of Methane Cycles and Trends at the WMO/GAW Station of Lamezia Terme (Calabria, Southern Italy)

IF 2.5 4区地球科学 Q3 ENVIRONMENTAL SCIENCES Atmosphere Pub Date : 2024-08-07 DOI:10.3390/atmos15080946

Francesco D’Amico, Ivano Ammoscato, Daniel Gullì, Elenio Avolio, Teresa Lo Feudo, Mariafrancesca De Pino, Paolo Cristofanelli, Luana Malacaria, Domenico Parise, Salvatore Sinopoli, Giorgia De Benedetto, Claudia Roberta Calidonna

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Abstract

Due to its high short-term global warming potential (GWP) compared to carbon dioxide, methane (CH4) is a considerable agent of climate change. This research is aimed at analyzing data on methane gathered at the GAW (Global Atmosphere Watch) station of Lamezia Terme (Calabria, Southern Italy) spanning seven years of continuous measurements (2016–2022) and integrating the results with key meteorological data. Compared to previous studies on detected methane mole fractions at the same station, daily-to-yearly patterns have become more prominent thanks to the analysis of a much larger dataset. Overall, the yearly increase of methane at the Lamezia Terme station is in general agreement with global measurements by NOAA, though local peaks are present, and an increase linked to COVID-19 is identified. Seasonal changes and trends have proved to be fully cyclic, with the daily cycles being largely driven by local wind circulation patterns and synoptic features. Outbreak events have been statistically evaluated depending on their weekday of occurrence to test possible correlations with anthropogenic activities. A cross analysis between methane peaks and specific wind directions has also proved that local sources may be deemed responsible for the highest mole fractions.

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世界气象组织/全球大气监测网拉梅齐亚泰尔梅站甲烷循环和趋势综合分析（意大利南部卡拉布里亚）

与二氧化碳相比，甲烷（CH4）具有较高的短期全球升温潜能值（GWP），是造成气候变化的重要因素。本研究旨在分析拉梅齐亚泰尔梅（意大利南部卡拉布里亚）GAW（全球大气观测）站收集的甲烷数据，这些数据已连续测量了七年（2016-2022 年），并将结果与主要气象数据进行了整合。与之前对同一站点检测到的甲烷摩尔分数进行的研究相比，由于分析了更大的数据集，从每天到每年的模式变得更加突出。总体而言，拉梅济亚泰尔梅站甲烷的年增长率与诺阿的全球测量结果基本一致，但也存在局部峰值，并发现了与 COVID-19 有关的增长。事实证明，季节变化和趋势是完全周期性的，日周期主要受当地风环流模式和天气特征的影响。根据爆发事件发生的工作日，对其进行了统计评估，以检验可能与人为活动的相关性。甲烷峰值与特定风向之间的交叉分析也证明，当地来源可被视为造成最高摩尔分数的原因。

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来源期刊

Atmosphere METEOROLOGY & ATMOSPHERIC SCIENCES-

CiteScore

4.60

自引率

13.80%

发文量

1769

审稿时长

1 months

期刊介绍： Atmosphere (ISSN 2073-4433) is an international and cross-disciplinary scholarly journal of scientific studies related to the atmosphere. It publishes reviews, regular research papers, communications and short notes, and there is no restriction on the length of the papers. Our aim is to encourage scientists to publish their experimental and theoretical research in as much detail as possible. Full experimental and/or methodical details must be provided for research articles.