共查询到19条相似文献,搜索用时 109 毫秒
1.
自政府间气候变化专门委员会(IPCC)第五次评估报告(AR5)发布以来,国际科学界在气候系统变化领域取得显著进展,有关气候变化的科学认识不断深入。IPCC第六次评估报告(AR6)第一工作组(WGI)报告对这些科学进展和最新认识作了综合评估。温度是全球变化最直接的指示器。本文从温度变化视角,对从AR5到AR6的科学进展进行了梳理和简要评述,主要聚焦观测的变化、归因以及未来预估三个方面。与AR5相比,AR6以更强有力的证据进一步确证了近百年全球气候变暖的客观事实,人类活动对气候变暖影响的信号更为清晰,未来变暖幅度取决于温室气体减排力度。 相似文献
2.
极端天气气候事件对社会经济与人类活动有明显影响,因此政策制定者和公众都很关心极端气候事件的变化。政府间气候变化专门委员会(IPCC)发表的4次评估报告都非常重视评估这方面的研究,自2007年第四次评估报告发表以来,对极端气候事件 相似文献
3.
由于全球气候变化,气温升高导致的极端天气气候事件发生的频率和强度也随之加大。针对这一有关全球的发展问题,文章参考“气候变化对增长和发展的影响”(斯特思报告第2部分)、“应对气候变化的政策响应”(斯特恩报告第5部分)以及日本东京大学工程研究生院Yuzuru Matsuoka等人的“气候变化综合评估模式:亚太综合模式(AIM)”,提出了气候变化对人类基本生活要素的影响,预估了温室气体“常规商务”(BAU)排放情况下气候变化可能对全球社会经济产生的潜在影响,讨论了适当气候变化产生的成本与效益,简介了斯特恩报告中采用的基本评估模式和亚太综合评估模式。 相似文献
4.
气候变化科学方面的几个最新认知 总被引:1,自引:0,他引:1
IPCC第六次评估报告(AR6)第一工作组报告主要从以下几个方面的进展提升了我们对气候系统变化、气候变化原因以及预估未来气候系统变化等方面的认知,对过去气候变化及其与人类活动的关系有了更加清晰、可靠的认识。综合多重证据评估指出,全球气候正经历着前所未有的变化;包括极端事件在内的归因进展已把人类活动对气候系统影响的认识从大气圈扩展到水圈、冰冻圈和生物圈,进一步强化了人类活动影响全球和区域气候的认识;有关区域气候变化信息的内容更加丰富,与各行业和敏感地区的气候变化影响联系更加紧密,使这些信息能更好地为气候变化风险评估和气候变化区域适应提供支持;气候模式和约束预估方法的发展以及对气候敏感度认识的深化,减少了未来不同排放情景下全球地表温度(Global Surface Temperature,GST)、海平面上升和海洋热含量的变化预估的不确定性。这份最新报告对我国提升气候变化研究水平和防灾减灾应对能力具有十分重要的指导意义。 相似文献
5.
6.
7.
IPCC第六次评估报告(AR6)第二工作组(WGⅡ)报告第七章《健康、福祉和不断变化的社区结构》评估了气候变化对健康和福祉的当前影响与未来风险,提出了应对气候变化的适应策略和适应限度。指出自AR5以来越来越多的证据表明,气候变化通过直接或间接方式对人类健康(包括精神健康)造成了负面影响,气候敏感性疾病、营养不良、过早死亡,以及对精神健康的威胁正在增加,气候相关的危害正日益影响越来越多的健康结局(包括传染性和非传染性疾病)和地区。在所有人类居住的地区,都观察到极端天气事件对健康造成的级联及复合风险,且风险还会随着全球变暖而进一步增大。扩大对卫生和其他系统的金融投资,加强跨部门和跨系统的整合与合作,创建气候恢复力发展路径,将适应和减缓纳入可持续发展目标,可以为健康和福祉带来巨大的协同效益,是降低人类健康风险的重要适应措施。 相似文献
8.
IPCC第五次评估报告气候变化对人类福祉影响的新认知 总被引:2,自引:0,他引:2
IPCC第五次评估报告(AR5)第二工作组(WGII)报告评估了气候变化对人类健康、人类安全、生计与贫困的影响,指出气候变化已经对人类健康和安全造成了负面影响,气候变化、气候变率和极端气候事件给城市和农村的贫困人口增添了额外的负担,与气候变化相关的风险增大。21世纪的气候变化,将继续加剧现有健康问题,增加人类的迁徙,放大冲突的驱动因素的影响,对许多国家的关键基础设施造成不利影响,给小岛国和有很长海岸线国家的领土完整带来风险;整个21世纪,气候变化将减缓经济增长,进一步威胁粮食安全,使减贫更为困难,贫困问题更加突出。 相似文献
9.
IPCC第六次评估报告(AR6)第一工作组报告(简称报告)中提供了对气候系统和气候变化的最新物理解释,整合了来自古气候和仪器观测的多项证据、过程理解以及全球和区域的气候模拟,记录了气候科学的最新进展。报告旨在提供有关过去气候如何变化的事实,揭示人类活动在这些变化中所起的作用,并根据不同社会经济路径的排放情景对未来气候进行了预估。这些结果对于政策制定者来说很重要。它有助于减缓气候变化、根据灾害管理框架制定区域适应计划以及开展即将到来的2023年全球综合评估。本文聚焦该报告的背景、架构和方法,并介绍当前气候变化评估的主要进展。结果显示,与以前的评估报告相比,AR6提供了更综合实用的信息和认识,更加强调了区域气候变化,以及更好地约束了气候敏感度的估计。该报告最重要的结论之一是人类活动对气候变化的影响已从科学认知演变为不争的事实。 相似文献
10.
11.
USE OF A STOCHASTIC WEATHER GENERATOR IN THE DEVELOPMENT OF CLIMATE CHANGE SCENARIOS 总被引:14,自引:0,他引:14
Climate change scenarios with a high spatial and temporal resolution are required in the evaluation of the effects of climate change on agricultural potential and agricultural risk. Such scenarios should reproduce changes in mean weather characteristics as well as incorporate the changes in climate variability indicated by the global climate model (GCM) used. Recent work on the sensitivity of crop models and climatic extremes has clearly demonstrated that changes in variability can have more profound effects on crop yield and on the probability of extreme weather events than simple changes in the mean values. The construction of climate change scenarios based on spatial regression downscaling and on the use of a local stochastic weather generator is described. Regression downscaling translated the coarse resolution GCM grid-box predictions of climate change to site-specific values. These values were then used to perturb the parameters of the stochastic weather generator in order to simulate site-specific daily weather data. This approach permits the incorporation of changes in the mean and variability of climate in a consistent and computationally inexpensive way. The stochastic weather generator used in this study, LARS-WG, has been validated across Europe and has been shown to perform well in the simulation of different weather statistics, including those climatic extremes relevant to agriculture. The importance of downscaling and the incorporation of climate variability are demonstrated at two European sites where climate change scenarios were constructed using the UK Met. Office high resolution GCM equilibrium and transient experiments. 相似文献
12.
Climate Extremes: Selected Review and Future Research Directions 总被引:10,自引:0,他引:10
13.
This paper reviews recent progress in climate change attribution studies. The focus is on the attribution of observed long-term changes in surface temperature, precipitation, circulation, and extremes, as well as that of specific extreme weather and climate events. Based on new methods and better models and observations, the latest studies further verify the conclusions on climate change attribution in the IPCC AR5, and enrich the evidence for anthropogenic influences on weather and climate variables and extremes. The uncertainty of global temperature change attributable to anthropogenic forcings lies in the considerable uncertainty of estimated total radiative forcing due to aerosols, while the uncertainty of precipitation change attribution arises from the limitations of observation and model simulations along with influences from large internal variability. In terms of extreme weather and climate events, it is clear that attribution studies have provided important new insights into the changes in the intensity or frequency of some of these events caused by anthropogenic climate change. The framing of the research question, the methods selected, and the model and statistical methods used all have influences on the results and conclusions drawn in an event attribution study. Overall, attribution studies in China remain inadequate because of limited research focus and the complexity of the monsoon climate in East Asia. Attribution research in China has focused mainly on changes or events related to temperature, such as the attribution of changes in mean and extreme temperature and individual heat wave events. Some progress has also been made regarding the pattern of changes in precipitation and individual extreme rainfall events in China. Nonetheless, gaps remain with respect to the attribution of changes in extreme precipitation, circulation, and drought, as well as to the event attribution such as those related to drought and tropical cyclones. It can be expected that, with the continual development of climate models, ongoing improvements to data, and the introduction of new methods in the future, climate change attribution research will develop accordingly. Additionally, further improvement in climate change attribution will facilitate the development of operational attribution systems for extreme events, as well as attribution studies of climate change impacts. 相似文献
14.
This paper offers insights for assessing organizational resilience to the effects of climate change, specifically to climate and weather extremes. The assessment of organizational resilience to climate and weather extremes brings about several challenges due to (1) uncertainties about future climate change outcomes across temporal and spatial scales and (2) a lack of insight into what lead to organizational resilience, or which variables should be measured in a given study. We suggest methodological pathways for organizational managers to identify properties of future climate and weather extremes and to include them in resilience assessments. We also suggest approaches to identify factors that promote organizational resilience to selected climate and weather extremes. Findings are intended to help managers to understand how organizational resilience to climate and weather extremes can be enhanced. 相似文献
15.
János Mika 《Climatic change》2013,121(1):15-26
The terms “weather extremes” and “climate extremes” are widely used in meteorology, often in relation to climate change. This paper reviews the empirical investigations into parallel changes in extreme events and climate change published in recent years and looks at their relevance for the global energy system. Empirical investigation into the correlation of extremes with global warming covers five groups: changes in temperature, precipitation, wind (storm) extremes, tropical and extra-tropical circulation phenomena. For temperature extremes, extensive analyses demonstrate that extreme hot days and nights will likely become more frequent, and extreme cold days and nights less frequent. Intense precipitation events will likely become more frequent in most continental regions. Scientific confidence in the trends of the frequency, duration, and intensity of tropical cyclones, is still low. A poleward shift is observed for extratropical cyclones, whereas no convincing tendencies of many smaller-scale phenomena, for example, tornados, or hail, can yet be detected. All these extremes have serious implications for the energy sector. 相似文献
16.
Global warming is expected to affect both the frequency and severity of extreme weather events, though projections of the response of these events to climate warming remain highly uncertain. The range of changes reported in the climate modelling literature is very large, sometimes leading to contradictory results for a given extreme weather event. Much of this uncertainty stems from the incomplete understanding of the physics of extreme weather processes, the lack of representation of mesoscale processes in coarse-resolution climate models, and the effect of natural climate variability at multi-decadal time scales. However, some of the spread in results originates simply from the variety of scenarios for future climate change used to drive climate model simulations, which hampers the ability to make generalizations about predicted changes in extreme weather events. In this study, we present a meta-analysis of the literature on projected future extreme weather events in order to quantify expected changes in weather extremes as a function of a common metric of global mean temperature increases. We find that many extreme weather events are likely to be significantly affected by global warming. In particular, our analysis indicates that the overall frequency of global tropical cyclones could decrease with global warming but that the intensity of these storms, as well as the frequency of the most intense cyclones could increase, particularly in the northwestern Pacific basin. We also found increases in the intensity of South Asian monsoonal rainfall, the frequency of global heavy precipitation events, the number of North American severe thunderstorm days, North American drought conditions, and European heatwaves, with rising global mean temperatures. In addition, the periodicity of the El Niño–Southern Oscillation may decrease, which could, in itself, influence extreme weather frequency in many areas of the climate system. 相似文献
17.
Synoptic weather typing and regression-based downscaling approaches have become popular in evaluating the impacts of climate change on a variety of environmental problems, particularly those involving extreme impacts. One of the reasons for the popularity of these approaches is their ability to categorize a complex set of meteorological variables into a coherent index, facilitating the projection of changes in frequency and intensity of future daily extreme weather events and/or their impacts. This paper illustrated the capability of the synoptic weather typing and regression methods to analyze climatic change impacts on a number of extreme weather events and environmental problems for south–central Canada, such as freezing rain, heavy rainfall, high-/low-streamflow events, air pollution, and human health. These statistical approaches are helpful in analyzing extreme events and projecting their impacts into the future through three major steps or analysis procedures: (1) historical simulation modeling to identify extreme weather events or their impacts, (2) statistical downscaling to provide station-scale future hourly/daily climate data, and (3) projecting changes in the frequency and intensity of future extreme weather events and their impacts under a changing climate. To realize these steps, it is first necessary to conceptualize the modeling of the meteorology, hydrology and impacts model variables of significance and to apply a number of linear/nonlinear regression techniques. Because the climate/weather validation process is critical, a formal model result verification process has been built into each of these three steps. With carefully chosen physically consistent and relevant variables, the results of the verification, based on historical observations of the outcome variables simulated by the models, show a very good agreement in all applications and extremes tested to date. Overall, the modeled results from climate change studies indicate that the frequency and intensity of future extreme weather events and their impacts are generally projected to significantly increase late this century over south–central Canada under a changing climate. The implications of these increases need be taken into consideration and integrated into policies and planning for adaptation strategies, including measures to incorporate climate change into engineering infrastructure design standards and disaster risk reduction measures. This paper briefly summarized these climate change research projects, focusing on the modeling methodologies and results, and attempted to use plain language to make the results more accessible and interesting to the broader informed audience. These research projects have been used to support decision-makers in south–central Canada when dealing with future extreme weather events under climate change. 相似文献
18.
Framing the way to relate climate extremes to climate change 总被引:3,自引:1,他引:2
Kevin E. Trenberth 《Climatic change》2012,115(2):283-290
The atmospheric and ocean environment has changed from human activities in ways that affect storms and extreme climate events. The main way climate change is perceived is through changes in extremes because those are outside the bounds of previous weather. The average anthropogenic climate change effect is not negligible, but nor is it large, although a small shift in the mean can lead to very large percentage changes in extremes. Anthropogenic global warming inherently has decadal time scales and can be readily masked by natural variability on short time scales. To the extent that interactions are linear, even places that feature below normal temperatures are still warmer than they otherwise would be. It is when natural variability and climate change develop in the same direction that records get broken. For instance, the rapid transition from El Ni?o prior to May 2010 to La Ni?a by July 2010 along with global warming contributed to the record high sea surface temperatures in the tropical Indian and Atlantic Oceans and in close proximity to places where record flooding subsequently occurred. A commentary is provided on recent climate extremes. The answer to the oft-asked question of whether an event is caused by climate change is that it is the wrong question. All weather events are affected by climate change because the environment in which they occur is warmer and moister than it used to be. 相似文献
19.
2014年9月,IPCC联合世界气候研究计划(WCRP),在瑞士伯尔尼大学召开了一次特别的研讨会,总结过去几年气候变化科学研究中所取得的经验教训。此次会议针对IPCC最新评估报告中的关键不确定性,梳理并总结了未来气候变化研究的主要科学方向和面临的主要挑战,讨论了如何与WCRP计划结合并解决这些问题,以期在未来更好地应对这些挑战。在此次会议上,与会专家提出,未来气候变化科学研究的重大挑战应包括如下8个主题。云、环流与气候敏感度;理解和预测极端天气气候事件;冰冻圈变化;区域气候信息;区域海平面上升及其对沿海地区的影响;水资源可利用量;生物地球化学、气溶胶和大气化学;理解年代际变化:归因与预测。这些主题涵盖了WCRP计划的六大挑战和其他被认为具有挑战性的主题。本文将在此次会议报告的基础上,对相关内容进行介绍,以供当前的气候变化工作参考。 相似文献