在事件归因背景下体现自然气候变异性:2022 年印巴热浪

IF 5.3 2区 材料科学 Q2 MATERIALS SCIENCE, MULTIDISCIPLINARY ACS Applied Nano Materials Pub Date : 2024-04-04 DOI:10.1016/j.wace.2024.100671
Shruti Nath , Mathias Hauser , Dominik L. Schumacher , Quentin Lejeune , Lukas Gudmundsson , Yann Quilcaille , Pierre Candela , Fahad Saeed , Sonia I. Seneviratne , Carl-Friedrich Schleussner
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引用次数: 0

摘要

将极端气候事件归因于人为温室气体排放导致的全球气候变化变得越来越重要。极端气候事件产生于自然气候变异性和地球系统对人为温室气体排放的被迫反应的交汇点,而人为温室气体排放可能会改变此类事件的频率和严重程度。因此,考虑到自然气候变异性和人为气候变化强迫响应的影响对于归因至关重要。在此,我们研究了在更明确地表示自然气候变异性的情况下,极端事件概率归因结果的可重复性。我们采用在统计地球系统模式模拟器中部署的成熟方法,根据时空协方差结构来表示自然气候变异性。我们研究了表示自然气候变异性的两种方法:(1) 将自然气候变异性视为单一成分;(2) 将自然气候变异性分解为年度和季节成分。我们通过将 2022 年印巴热浪归因于人为气候变化来展示我们的方法。我们发现,与 "世界天气归因倡议"(World Weather Attribution Initiative)等既有方法相比,明确表示年度和季节性自然气候变率会大大增加归因结果的整体不确定性。全球变暖导致此类事件发生的可能性增加程度在不同方法之间略有不同,这主要是由于对工业化前重现期的评估不同。我们的方法明确解决了年度和季节性自然气候变异性问题,表明可能性中位数增加了 41 倍(95% 范围:6-603)。我们发现,在所有方法中,随着全球变暖水平的增加,该事件发生的可能性和强度都会增加。与目前的可能性相比,在全球近地面气温相对于工业化前温度上升 1.5 ℃(2 ℃)的情况下,该事件的可能性将增加 2.2 到 2.5 倍(8 到 9 倍)。我们注意到,无论采用哪种不同的统计方法来表示自然变率,对已发生事件的归因结果都是相似的,主要在不确定性范围上存在细微差别。我们对造成差异的可能原因进行了评估,包括拟议方法在此类应用中的局限性,以及该方法可为既定方法提供补充信息的具体方面。
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Representing natural climate variability in an event attribution context: Indo-Pakistani heatwave of 2022

Attribution of extreme climate events to global climate change as a result of anthropogenic greenhouse gas emissions has become increasingly important. Extreme climate events arise at the intersection of natural climate variability and a forced response of the Earth system to anthropogenic greenhouse gas emissions, which may alter the frequency and severity of such events. Accounting for the effects of both natural climate variability and the forced response to anthropogenic climate change is thus central for the attribution. Here, we investigate the reproducibility of probabilistic extreme event attribution results under more explicit representations of natural climate variability. We employ well-established methodologies deployed in statistical Earth System Model emulators to represent natural climate variability as informed from its spatio-temporal covariance structures. Two approaches towards representing natural climate variability are investigated: (1) where natural climate variability is treated as a single component; and (2) where natural climate variability is disentangled into its annual and seasonal components. We showcase our approaches by attributing the 2022 Indo-Pakistani heatwave to human-induced climate change. We find that explicit representation of annual and seasonal natural climate variability increases the overall uncertainty in attribution results considerably compared to established approaches such as the World Weather Attribution Initiative. The increase in likelihood of such an event occurring as a result of global warming differs slightly between the approaches, mainly due to different assessments of the pre-industrial return periods. Our approach that explicitly resolves annual and seasonal natural climate variability indicates a median increase in likelihood by a factor of 41 (95% range: 6-603). We find a robust signal of increased likelihood and intensification of the event with increasing global warming levels across all approaches. Compared to its present likelihood, under 1.5 °C (2 °C) of global near-surface air temperature increase relative to pre-industrial temperatures, the likelihood of the event would be between 2.2 to 2.5 times (8 to 9 times) higher. We note that regardless of the different statistical approaches to represent natural variability, the outcomes on the conducted event attribution are similar, with minor differences mainly in the uncertainty ranges. Possible reasons for differences are evaluated, including limitations of the proposed approach for this type of application, as well as the specific aspects in which it can provide complementary information to established approaches.

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来源期刊
CiteScore
8.30
自引率
3.40%
发文量
1601
期刊介绍: ACS Applied Nano Materials is an interdisciplinary journal publishing original research covering all aspects of engineering, chemistry, physics and biology relevant to applications of nanomaterials. The journal is devoted to reports of new and original experimental and theoretical research of an applied nature that integrate knowledge in the areas of materials, engineering, physics, bioscience, and chemistry into important applications of nanomaterials.
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