气候变化下全球和区域火灾趋势及驱动因素

IF 25.2 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
Matthew W. Jones, John T. Abatzoglou, Sander Veraverbeke, Niels Andela, Gitta Lasslop, Matthias Forkel, Adam J. P. Smith, Chantelle Burton, Richard A. Betts, Guido R. van der Werf, Stephen Sitch, Josep G. Canadell, Cristina Santín, Crystal Kolden, Stefan H. Doerr, Corinne Le Quéré
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引用次数: 101

摘要

最近世界各地发生的野火引发了人们的担忧,即气候变化正在增加火灾发生率,威胁人类生计和生物多样性,并使气候变化永久化。在这里,我们回顾了目前对气候变化对火灾天气(有利于野火着火和蔓延的天气条件)的影响以及一系列其他生物气候因素(包括植被、生物地理、生产力和闪电)和人为因素(包括着火、扑灭和土地利用)介导的区域火灾活动的后果的理解。通过补充分析,我们总结了近几十年来火灾天气和烧伤面积(BA)的区域趋势,并研究了火灾活动与生物气候和人类驱动因素的关系。火灾天气控制着世界上大多数地区的年度火灾时间,也驱动着地中海、太平洋美国和高纬度森林的BA年际变化。1979年至2019年期间,由于气候变化,火灾天气的频率和极端程度在全球范围内普遍增加,这意味着景观将更频繁地燃烧。相应地,在2001-2019年期间,包括美国太平洋和高纬度森林在内的一些温带森林生态区的BA增加了~ 50%或更高,尽管这些地区的年际变率仍然很大。尽管如此,其他生物气候和人为因素可以超越BA和火灾天气之间的关系。例如,大草原上的BA与燃料生产模式或农业对自然火灾易发景观的破坏关系更大。同样,热带森林的BA趋势与毁林率和森林退化的关系比与变化的火灾天气的关系更大。总的来说,在过去的二十年里,全球的BA减少了27%,这在很大程度上是由于非洲大草原BA的减少。根据气候模型,由于气候变化,地中海地区火灾天气的流行程度和极端程度已经超出了工业化前的多变性,而且在额外的变暖水平下,火灾天气的出现将变得越来越普遍。此外,近年来发生的几起重大野火,包括2019/2020年的澳大利亚森林大火,都是在火灾天气条件下发生的,而气候变化更有可能导致火灾天气条件。目前的火灾模型基于现有的火灾及其生物气候和人类控制之间关系的表征,不能完全再现观测到的BA空间格局,并且不同模型之间BA的历史趋势也存在很大差异。对火灾的观察和对其控制因素的理解的进展正在支持模型中一系列过程的添加或优化。总体而言,气候变化通过增加火灾天气的频率和强度,正在全球范围内对火灾施加普遍的上行压力,并且这种上行压力将随着全球变暖的每一次增加而升级。为了预测未来的火灾活动并减轻其后果,需要改进火灾模型,更好地了解气候、极端气候、人类和火灾之间的相互作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Global and Regional Trends and Drivers of Fire Under Climate Change

Recent wildfire outbreaks around the world have prompted concern that climate change is increasing fire incidence, threatening human livelihood and biodiversity, and perpetuating climate change. Here, we review current understanding of the impacts of climate change on fire weather (weather conditions conducive to the ignition and spread of wildfires) and the consequences for regional fire activity as mediated by a range of other bioclimatic factors (including vegetation biogeography, productivity and lightning) and human factors (including ignition, suppression, and land use). Through supplemental analyses, we present a stocktake of regional trends in fire weather and burned area (BA) during recent decades, and we examine how fire activity relates to its bioclimatic and human drivers. Fire weather controls the annual timing of fires in most world regions and also drives inter-annual variability in BA in the Mediterranean, the Pacific US and high latitude forests. Increases in the frequency and extremity of fire weather have been globally pervasive due to climate change during 1979–2019, meaning that landscapes are primed to burn more frequently. Correspondingly, increases in BA of ∼50% or higher have been seen in some extratropical forest ecoregions including in the Pacific US and high-latitude forests during 2001–2019, though interannual variability remains large in these regions. Nonetheless, other bioclimatic and human factors can override the relationship between BA and fire weather. For example, BA in savannahs relates more strongly to patterns of fuel production or to the fragmentation of naturally fire-prone landscapes by agriculture. Similarly, BA trends in tropical forests relate more strongly to deforestation rates and forest degradation than to changing fire weather. Overall, BA has reduced by 27% globally in the past two decades, due in large part to a decline in BA in African savannahs. According to climate models, the prevalence and extremity of fire weather has already emerged beyond its pre-industrial variability in the Mediterranean due to climate change, and emergence will become increasingly widespread at additional levels of warming. Moreover, several of the major wildfires experienced in recent years, including the Australian bushfires of 2019/2020, have occurred amidst fire weather conditions that were considerably more likely due to climate change. Current fire models incompletely reproduce the observed spatial patterns of BA based on their existing representations of the relationships between fire and its bioclimatic and human controls, and historical trends in BA also vary considerably across models. Advances in the observation of fire and understanding of its controlling factors are supporting the addition or optimization of a range of processes in models. Overall, climate change is exerting a pervasive upwards pressure on fire globally by increasing the frequency and intensity of fire weather, and this upwards pressure will escalate with each increment of global warming. Improvements to fire models and a better understanding of the interactions between climate, climate extremes, humans and fire are required to predict future fire activity and to mitigate against its consequences.

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来源期刊
Reviews of Geophysics
Reviews of Geophysics 地学-地球化学与地球物理
CiteScore
50.30
自引率
0.80%
发文量
28
审稿时长
12 months
期刊介绍: Geophysics Reviews (ROG) offers comprehensive overviews and syntheses of current research across various domains of the Earth and space sciences. Our goal is to present accessible and engaging reviews that cater to the diverse AGU community. While authorship is typically by invitation, we warmly encourage readers and potential authors to share their suggestions with our editors.
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