全球变暖与城市效应共同作用下的极端天气气候事件变化的最新认知

近年来,城市气候变化问题引起高度关注。综合IPCC第一工作组第六次评估报告(IPCC AR6)关于气候变暖背景下城市对极端天气气候事件影响的评估,本文得到以下科学认识：城市化加剧了局部气候变暖,全球许多城市都面临更多更强的高温热浪事件;城市化使得诸多城市区域及其下风向极端降水增加,地表径流加强;沿海城市受到日益加剧的与海平面上升有关的复合型洪水的影响;城市污染物排放和不利通风的建筑结构加剧了区域污染,同时增加了地表的臭氧含量。预计未来城市极端高温、极端降水及有关洪水事件将更为频发,空气污染形势更为严峻,气候变化风险进一步加大。中国城镇化进程迅速,需要进一步加强气候变化背景下城市极端事件的观测、形成机理和数值模拟研究,以提升城市极端事件风险认识水平和应对能力。     

辽源天气与城市用水量关系的探讨

1引言 随着经济的迅猛发展和城市规模的不断扩大，城市的工业用水和居民生活用水不断增加，而近几年严重的干旱，使得水库蓄水量严重不足，而城市用水主要是来自水库。因此，城市用水严重缺少就十分突出。如何科学调度、科学用水、节约用水就十分重要。而用水量的多少又与天气变化非常密切，尤其是在夏季，长时间的高温、酷暑，久雨转晴，春末的第一次高温等，城市用水量都会剧增。如果自来水公司事先不知晓，没有做好充分的准备，提前多生产自来水，就会引起自来水水压下降，甚至停水，影响城市工业和居民生活用水。     

极端天气和气候事件的变化

自1950年以来的观测证据表明,有些极端天气和气候事件已经发生了变化。全球尺度上,人为影响可能已经导致极端日最低和最高温度升高;由于平均海平面上升,人类活动可能已对沿海极端高水位事件的增加产生了影响;具有中等信度的是,人为影响已导致全球强降水增加;由于热带气旋历史记录的不确定性、缺乏对热带气旋与气候变化之间关联的物理机制的完整认识及热带气旋自然变率的程度,将可检测到的热带气旋活动变化归因于人为影响仅具有低信度。将单一的极端事件变化归因于人为气候变化具有挑战性。对极端事件变化预估的信度取决于事件的类型、区域和季节、观测资料的数量和质量、基本物理过程的认知水平及模式对其模拟的可靠性。     

浙江省极端气温事件年代际变化特征及城乡差异分析

采用百分位法确定了极端温度事件,通过t检验法、气候倾向率分析了极端温度事件的年代际及年际变化特征,基于核密度估计方法揭示了四季极端温度事件年代际变化特征及城乡差异。结果表明:极端高温和低温日数分别呈现以增加为主和以减少为主的变化特征,这种趋势随时间增强,东部沿海地区最显著。四季极端高温日数增多、强度增大,夏季增多最多、冬季最少,强度增大在春冬季最强。四季极端低温日数减少、强度减小,冬季减少最多,强度减小在春季最强。浙西地区极端温度事件的年际变率小于浙东地区,浙江城市地区四季极端高温强度更强、极端低温强度更弱。     

1961~2010年西北地区极端气候事件变化特征

利用1961~2010年西北地区131个气象站的逐日平均气温、最高和最低气温及逐日降水资料,分析了西北地区极端气候事件的变化趋势及空间分布特征。结果表明:气候变暖背景下,西北地区近50 a来气温整体呈增加趋势,极端高温事件增多,极端低温事件减少;降水量呈微弱的增加趋势,极端降水事件增多;极端高温日数分别在1982年和1996年发生转折,95%、99%极端低温日数均在1980年前后发生突变,95%、99%极端降水日数分别在2000年和1980年出现转折,这与气温和降水的变化趋势一致。极端低温日数减少的幅度大于极端高温日数增加的幅度,表明气温日较差呈减小趋势,存在非对称性增温特征。空间上,增温率大的区域其极端高温日数增加,极端低温日数显著减少;95%、99%极端降水日数增率大的区域多位于降水量倾向率较高的地区。     

东亚区域极端气候事件变化的数值模拟试验

使用ResCM2区域气候模式,嵌套澳大利亚CSIRO R21L9全球海气耦合模式,进行了温室效应（二氧化碳加倍）对东亚（主要是中国区域）极端气候事件影响的数值试验。控制试验的结果表明,区域模式能够较好地模拟中国区域的极端气候事件。对温室效应引起的它们的变化进行了信度检验,分析结果表明,温室效应将引起日最高和最低气温增加,日较差减小;使得高温天气增多,低温日数减少。降水日数和大雨日数在一些地区将增加。同时还会引起影响中国的台风活动的变化。     

山东夏季极端热事件变化特征分析

利用山东88个气象站1961—2019年夏季6—8月逐日最高、最低气温观测数据,分析了山东各地极端热昼、极端热夜、极端高温日三个极端热事件的时空演变规律和突变特征。结果表明：1）山东夜间出现极端热事件及白天和夜间同时出现极端热事件的天数增多、强度增强、占比增加。历年极端热昼出现天数和占比均呈不同程度的减少趋势,平均强度呈减小趋势,其中占比减少最明显;极端热夜、极端高温日出现天数和占比均呈不同程度的增加趋势,平均强度呈增强趋势。2）山东内陆和沿海地区各极端热事件变化差异明显。内陆地区极端热昼各指标减少、减小趋势更显著,大部分地区变化趋势通过了0.05的显著性水平检验,半岛南部和东部部分区域则有增加、增强趋势;中西部地区极端热夜各指标增加、增强趋势更显著,大部分地区变化趋势通过了0.05的显著性水平检验;中东部区域尤其是半岛地区极端高温日各指标增加、增强趋势更显著,大部分地区变化趋势通过了0.05的显著性水平检验。3）各极端热事件不同指标的突变情况迥异。极端热昼历年出现天数没有发生突变,平均强度在1970年前后发生突变,突变发生后,平均强度明显减小;极端热夜出现天数和平均强度均在1994年前后发生突变,突变发生后,出现天数明显增加、平均强度明显增强;极端高温日出现天数和强度分别在1994年、1973年前后发生突变,突变发生后,出现天数明显增加。     

1957-2005年河南省降水和温度极端事件变化

利用河南省1957-2005年逐日降水,最高、最低和日平均气温资料,分析了近50 a河南省极端天气事件的变化趋势。结果表明：1957-2005年河南省暴雨日数、极端降水事件和严重干燥事件发生频率都在增加,但其线性趋势并不显著;暴雨和极端降水的变化趋势呈明显的南北差异;异常高温事件增加而异常低温事件减少,暖冬的趋势比较显著;高温日数和低温日数都显著减少,其变化趋势的空间分布具有很好的一致性。     

1957-2005年河南省降水和温度极端事件变化

 利用河南省1957-2005年逐日降水,最高、最低和日平均气温资料,分析了近50 a河南省极端天气事件的变化趋势。结果表明：1957-2005年河南省暴雨日数、极端降水事件和严重干燥事件发生频率都在增加,但其线性趋势并不显著;暴雨和极端降水的变化趋势呈明显的南北差异;异常高温事件增加而异常低温事件减少,暖冬的趋势比较显著;高温日数和低温日数都显著减少,其变化趋势的空间分布具有很好的一致性。     

极端气温事件对安徽省农业生产的动态影响分析

用安徽省17个城市逐日的最高气温、最低气温数据,采用百分位法计算了1988—2010年安徽省年际极端气温事件,并以计量经济学的结构向量自回归模型为基础,将极端气温事件作为一个因子与农业总产值、国内生产总值、农业机械总动力构建了新的经济-极端气温事件模型。进一步通过脉冲响应函数和方差分解方法,定量分析了极端气温事件对安徽省农业生产的动态影响,结果表明:极端高温事件对农业生产的影响总体为负向,并表现出一定的滞后性;而极端低温事件对农业生产的影响初期为正向,后期逐渐转为负向。极端高温事件对农业生产的影响程度较高,可达0.033%,极端低温事件次之。模型内引起农业生产变化的各因子中,极端高温事件的贡献比例可达25.3%,是重要的影响因子;极端低温事件的贡献比例最高为10.9%,也是比较主要的影响因子。     

IPCC AR6报告解读：气候变化与水安全

保障水安全是应对和缓解气候变化的核心问题,也是实现可持续发展的前提。IPCC第六次评估报告（AR6）第二工作组报告单独设立第四章“水”,分析了气候变化对全球水循环的影响,评估了水循环变化对人类社会和生态系统的影响,指出了当前与未来的水安全风险,分析了与水相关适应措施的收益与成效。报告显示,人类活动导致的气候变化加速了全球水文循环,对水安全产生负面影响,面临水安全风险的人口与地区增多,并增加了由社会经济因素造成的水资源脆弱性。水安全风险随全球升温水平的升高而增加,在水安全脆弱地区表现更为显著。将全球升温限制在1.5℃可有效降低未来的水安全风险,有助于实现水安全、可持续发展和具有气候恢复力的发展三重目标。我国水安全问题突出,急需在“灰-绿”基础设施生态水文效应、三维水资源短缺、水-粮食-能源耦合、地球系统模拟器研发应用等方面重点开展研究工作。     

气候变化对长江上游径流影响预估

利用第五次国际耦合模式比较计划(CMIP5)中5个气候模式在3种典型浓度路径(RCPs)下的预估结果驱动SWAT水文模型,预估了21世纪气候变化对长江上游年径流量、季节分配以及极端径流的影响。结果表明：预估的长江上游平均气温呈显著上升趋势,21世纪末较当前(1986—2005年)升高1.5~5.5℃,降水总体呈增加趋势,在21世纪30年代后高于当前气候平均值,21世纪末相对于当前增加5%~15%。流域内气候变化存在明显空间差异,金沙江和岷沱江流域气温升高和降水增加幅度均大于流域平均值。预估的长江上游年径流量及各月平均径流均有增加趋势,在21世纪30年代后高于当前多年平均值,21世纪中期增加4%~8%,21世纪末增加10%~15%。预估的径流年内分布的均匀性有所增加,但年际变化明显增大,极端旱涝事件的频率和强度明显增加。预估的各子流域径流变化对气候变化的响应也存在差异,金沙江和岷沱江流域年径流量、年际变化和年内分布变化小,对气候变化的响应表现为低敏感;嘉陵江流域、乌江流域和长江上游干流径流增加幅度大,同时极端丰枯出现的频率和程度增加显著,是气候变化响应的敏感区域。     

Water resources for agriculture in a changing climate: international case studies

This integrated study examines the implications of changes in crop water demand and water availability for the reliability of irrigation, taking into account changes in competing municipal and industrial demands, and explores the effectiveness of adaptation options in maintaining reliability. It reports on methods of linking climate change scenarios with hydrologic, agricultural, and planning models to study water availability for agriculture under changing climate conditions, to estimate changes in ecosystem services, and to evaluate adaptation strategies for the water resources and agriculture sectors. The models are applied to major agricultural regions in Argentina, Brazil, China, Hungary, Romania, and the US, using projections of climate change, agricultural production, population, technology, and GDP growth.For most of the relatively water-rich areas studied, there appears to be sufficient water for agriculture given the climate change scenarios tested. Northeastern China suffers from the greatest lack of water availability for agriculture and ecosystem services both in the present and in the climate change projections. Projected runoff in the Danube Basin does not change substantially, although climate change causes shifts in environmental stresses within the region. Northern Argentina's occasional problems in water supply for agriculture under the current climate may be exacerbated and may require investments to relieve future tributary stress. In Southeastern Brazil, future water supply for agriculture appears to be plentiful. Water supply in most of the US Cornbelt is projected to increase in most climate change scenarios, but there is concern for tractability in the spring and water-logging in the summer.Adaptation tests imply that only the Brazil case study area can readily accommodate an expansion of irrigated land under climate change, while the other three areas would suffer decreases in system reliability if irrigation areas were to be expanded. Cultivars are available for agricultural adaptation to the projected changes, but their demand for water may be higher than currently adapted varieties. Thus, even in these relatively water-rich areas, changes in water demand due to climate change effects on agriculture and increased demand from urban growth will require timely improvements in crop cultivars, irrigation and drainage technology, and water management.     

Risk assessment of agricultural water requirement based on a multi-model ensemble framework,southwest of Iran

Water shortage and climate change are the most important issues of sustainable agricultural and water resources development. Given the importance of water availability in crop production, the present study focused on risk assessment of climate change impact on agricultural water requirement in southwest of Iran, under two emission scenarios (A2 and B1) for the future period (2025–2054). A multi-model ensemble framework based on mean observed temperature-precipitation (MOTP) method and a combined probabilistic approach Long Ashton Research Station-Weather Generator (LARS-WG) and change factor (CF) have been used for downscaling to manage the uncertainty of outputs of 14 general circulation models (GCMs). The results showed an increasing temperature in all months and irregular changes of precipitation (either increasing or decreasing) in the future period. In addition, the results of the calculated annual net water requirement for all crops affected by climate change indicated an increase between 4 and 10 %. Furthermore, an increasing process is also expected regarding to the required water demand volume. The most and the least expected increase in the water demand volume is about 13 and 5 % for A2 and B1 scenarios, respectively. Considering the results and the limited water resources in the study area, it is crucial to provide water resources planning in order to reduce the negative effects of climate change. Therefore, the adaptation scenarios with the climate change related to crop pattern and water consumption should be taken into account.

     

The importance of population,climate change and CO2 plant physiological forcing in determining future global water stress

Future levels of water stress depend on changes in several key factors including population, climate-change driven water availability, and a carbon dioxide physiological-forcing effect on evaporation and run-off. In this study we use an ensemble of the HadCM3 climate model forced with a range of future emissions scenarios combined with a simple water scarcity index to assess the contribution of each of these factors to the projected population living in water stress over the 21st century.Population change only scenarios increase the number of people living in water stress such that at peak global population 65% of people experience some level of water stress. Globally, the climate model ensemble projects an increase in water availability which partially offsets some of the impacts of population growth. The result is 1 billion fewer people living in water stress by the 2080s under the high end emissions scenarios than if population increased in the absence of climate change.This study highlights the important role plant-physiological forcing has on future water resources. The effect of rising CO₂ is to increase available water and to reduce the number of people living in high water stress by around 200 million compared to climate only projections. This effect is of a similar order of magnitude to climate change.     

Evolution of the Parisian urban climate under a global changing climate

The evolution of the Parisian urban climate under a changing climate is analyzed from long-term offline numerical integrations including a specific urban parameterization. This system is forced by meteorological conditions based on present-climate reanalyses (1970–2007), and climate projections (2071–2099) provided by global climate model simulations following two emission scenarios (A1B and A2). This study aims at quantifying the impact of climate change on air temperature within the city and in the surroundings. A systematic increase of 2-meter air temperature is found. In average according to the two scenarios, it reaches +?2.0/2.4°C in winter and +?3.5/5.0°C in summer for the minimum and maximum daily temperatures, respectively. During summer, the warming trend is more pronounced in the surrounding countryside than in Paris and suburbs due to the soil dryness. As a result, a substantial decrease of the strong urban heat islands is noted at nighttime, and numerous events with negative urban heat islands appear at daytime. Finally, a 30% decrease of the heating degree days is quantified in winter between present and future climates. Inversely, the summertime cooling degree days significantly increase in future climate whereas they are negligible in present climate. However, in terms of accumulated degree days, the increase of the demand in cooling remains smaller than the decrease of the demand in heating.     

Future Precipitation Extremes in China under Climate Change and Their Physical Quantification Based on a Regional Climate Model and CMIP5 Model Simulations

The atmospheric water holding capacity will increase with temperature according to Clausius-Clapeyron scaling and affects precipitation.The rates of change in future precipitation extremes are quantified with changes in surface air temperature.Precipitation extremes in China are determined for the 21st century in six simulations using a regional climate model,RegCM4,and 17 global climate models that participated in CMIP5.First,we assess the performance of the CMIP5 models and RCM runs in their simulation of extreme precipitation for the current period(RF:1982-2001).The CMIP5 models and RCM results can capture the spatial variations of precipitation extremes,as well as those based on observations:OBS and XPP.Precipitation extremes over four subregions in China are predicted to increase in the mid-future(MF:2039-58)and far-future(FF:2079-98)relative to those for the RF period based on both the CMIP5 ensemble mean and RCM ensemble mean.The secular trends in the extremes of the CMIP5 models are predicted to increase from 2008 to 2058,and the RCM results show higher interannual variability relative to that of the CMIP5 models.Then,we quantify the increasing rates of change in precipitation extremes in the MF and FF periods in the subregions of China with the changes in surface air temperature.Finally,based on the water vapor equation,changes in precipitation extremes in China for the MF and FF periods are found to correlate positively with changes in the atmospheric vertical wind multiplied by changes in surface specific humidity(significant at the p<0.1 level).     

Assessing climate change impacts on the Iberian power system using a coupled water-power model

Climate change is expected to have a negative impact on the power system of the Iberian Peninsula; changes in river runoff are expected to reduce hydropower generation, while higher temperatures are expected to increase summer electricity demand, when water resources are already limited. However, these impacts have not yet been evaluated at the peninsular level. We coupled a hydrological model with a power market model to study three impacts of climate change on the current Iberian power system: changes in hydropower production caused by changes in precipitation and temperature, changes in temporal patterns of electricity demand caused by temperature changes, and changes in irrigation water use caused by temperature and precipitation changes. A stochastic dynamic programming approach was used to develop operating rules for the integrated system given hydrological uncertainty. We found that changes in precipitation will reduce runoff, decrease hydropower production (with accompanying increases in thermal generation), and increase irrigation water use, while higher temperatures will shift power demand from winter to summer months. The combined impact of these effects will generally make it more challenging to balance agricultural, power, and environmental objectives in the operation of Iberian reservoirs, though some impacts could be mitigated by better alignment between temporal patterns of irrigation and power demands.     

The implications of climate policy for the impacts of climate change on global water resources

This paper assesses the implications of climate policy for exposure to water resources stresses. It compares a Reference scenario which leads to an increase in global mean temperature of 4 °C by the end of the 21st century with a Mitigation scenario which stabilises greenhouse gas concentrations at around 450 ppm CO₂e and leads to a 2 °C increase in 2100. Associated changes in river runoff are simulated using a global hydrological model, for four spatial patterns of change in temperature and rainfall. There is a considerable difference in hydrological change between these four patterns, but the percentages of change avoided at the global scale are relatively robust. By the 2050s, the Mitigation scenario typically avoids between 16 and 30% of the change in runoff under the Reference scenario, and by 2100 it avoids between 43 and 65%. Two different measures of exposure to water resources stress are calculated, based on resources per capita and the ratio of withdrawals to resources. Using the first measure, the Mitigation scenario avoids 8-17% of the impact in 2050 and 20-31% in 2100; with the second measure, the avoided impacts are 5-21% and 15-47% respectively. However, at the same time, the Mitigation scenario also reduces the positive impacts of climate change on water scarcity in other areas. The absolute numbers and locations of people affected by climate change and climate policy vary considerably between the four climate model patterns.     

Adjusting water resources management to climate change

The nature of climate impacts and adjustment in water supply and flood management is discussed, and a case study of water manager response to climate fluctuation in California's Sacramento Basin is presented. The case illuminates the effect on climate impact and response of traditional management approaches, the dynamic qualities of maturing water systems, socially imposed constraints, and climate extremes. A dual pattern of crisisresponse and gradual adjustment emerges, and specific mechanisms for effecting adjustment of water management systems are identified. The case study, and broader trends in U.S. water development, suggest that oversized structural capacity, the traditional adjustment to climate variability in water resources, may prove less feasible in the future as projects become smaller and new facilities are delayed by economic and environmental concerns.