Satellite-Based Quantification of Contrail Radiative Forcing over Europe: A Two-Week Analysis of Aviation-Induced Climate Effects

arXiv - PHYS - Atmospheric and Oceanic Physics Pub Date : 2024-09-16 DOI:arxiv-2409.10166

Irene Ortiz, Ermioni Dimitropoulou, Pierre de Buyl, Nicolas Clerbaux, Javier García-Heras, Amin Jafarimoghaddam, Hugues Brenot, Jeroen van Gent, Klaus Sievers, Evelyn Otero, Parthiban Loganathan, Manuel Soler

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Abstract

Aviation's non-CO$_2$ effects, especially the impact of aviation-induced contrails, drive atmospheric changes and can influence climate dynamics. Although contrails are believed to contribute to global warming through their net warming effect, uncertainties persist due to the challenges in accurately measuring their radiative impacts. This study aims to address this knowledge gap by investigating the relationship between aviation-induced contrails, as observed in Meteosat Second Generation (MSG) satellite imagery, and their impact on radiative forcing (RF) over a two-week study. Results show that while daytime contrails generally have a cooling effect, the higher number of nighttime contrails results in a net warming effect over the entire day. Net RF values for detected contrails range approximately from -8 TW to 2.5 TW during the day and from 0 to 6 TW at night. Our findings also show a 41.03% increase in contrail coverage from January 24-30, 2023, to the same week in 2024, accompanied by a 128.7% rise in contrail radiative forcing (CRF), indicating greater warming from the added contrails. These findings highlight the necessity of considering temporal factors, such as the timing and duration of contrail formation, when assessing their overall warming impact. They also indicate a potential increase in contrail-induced warming from 2023 to 2024, attributable to the rise in contrail coverage. Further investigation into these trends is crucial for the development of effective mitigation strategies.

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基于卫星的欧洲上空烟云辐射强迫量化：对航空诱发气候效应的两周分析

航空的非 CO$_2$ 效应，尤其是航空诱发的烟尘的影响，推动了大气变化，并可能影响气候动力学。虽然人们认为烟尘通过其净变暖效应导致全球变暖，但由于难以准确测量其辐射影响，不确定性依然存在。本研究旨在通过调查气象卫星第二代（MSG）卫星图像中观测到的航空诱发的烟雾与它们对辐射强迫（RF）的影响之间的关系，弥补这一知识空白。研究结果表明，白天的飞行轨迹通常会产生降温效应，而夜间飞行轨迹数量较多，则会导致全天的净升温效应。探测到的忌雾的净射频值白天大约在-8 TW 到 2.5 TW 之间，夜间在 0 TW 到 6 TW 之间。我们的研究结果还显示，从 2023 年 1 月 24 日至 30 日，到 2024 年的同一周，禁飞区的覆盖范围增加了 41.03%，同时禁飞区辐射强迫（CRF）上升了 128.7%，这表明增加的禁飞区产生了更大的变暖效应。这些发现突出表明，在评估其对气候变暖的总体影响时，有必要考虑时间因素，如烟云形成的时间和持续时间。这些发现还表明，从 2023 年到 2024 年，由飞行物引起的气候变暖可能会增加，这归因于飞行物覆盖范围的扩大。进一步调查这些趋势对于制定有效的减缓战略至关重要。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Atmospheric and Oceanic Physics

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