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1.
1979~2004年中国大陆南方地区春季降水的年代际变化特征及其与欧亚大陆积雪的联系 总被引:1,自引:0,他引:1
本文研究了中国南方春季降水在1979~2004年期间的年代际变化特征,结果表明无论在年际还是在年代际时间尺度上,中国南方东南和西南地区降水都具有反相变化的特征,并分别呈现出显著的减少趋势和增加趋势.中国南方春季降水在20世纪80年代末出现了一次明显的年代际气候转型.东南地区的春季降水明显减少,降水量在80年代末以后比80年代末之前减少了30%;而西南地区的春季降水则明显增加,80年代末之后的降水量是80年代末之前的两倍.伴随着这次年代际转型,欧亚大陆西伯利亚上空对流层中低层位势高度增强,对流层低层中国东部北风增强,造成中国东部西南风减弱,使得降水在东南地区减少,西南地区增多.中国南方春季降水在20世纪80年代末出现的年代际气候转型与欧亚大陆春季积雪的年代际转型有密切联系.从20世纪80年代末开始欧亚大陆春季积雪明显减少,与欧亚大陆春季积雪变化所伴随的大气环流变化,是造成春季我国东南地区降水减少和西南地区降水增多的一个重要原因. 相似文献
2.
中国气候干湿变率与ENSO的关系及其稳定性 总被引:8,自引:0,他引:8
利用1951-01~2000-10中国160站气温和降水月平均资料, 计算了自修正PDSI指数. PDSI指数EOF分析第一模态空间场分布和1951~2000年PDSI指数的变化趋势分布十分相似, 第一模态时间系数反映了空间场随时间的演变情况. 研究发现, EOF分析所揭示的中国气候干湿变率和ENSO有着很好的关系. 这种关系表明, 在典型的ENSO暖状态, 中国大部分地区都偏干, 特别是华北地区更易偏干, 长江以南地区和西北容易偏湿, 而长江中下游地区处于变干和湿的过渡区, 变干或湿不明显. 在典型的ENSO冷状态则情况相反. 而中国气候干湿变率年际和年代际变化都对应着强El Niño事件; 反过来当发生强El Niño事件时, 中国气候干湿变率在年际和年代际尺度上有可能发生剧烈变化. 最近20~30 a中国气候干湿的年代际变化, 特别是华北自20世纪70年代末的变干和西北自80年代中期的变湿, 与ENSO朝更暖的状态变化及全球变暖有着紧密的联系. 1951~2000年中国气候干湿变率和ENSO关系的稳定性分析表明, 中国气候干湿变率和ENSO之间在3~8 a变化周期上存着很好的相关关系, 但这种相关关系不稳定, 存在着年代际变化: 1951~1962和1976~1991年两个时间段两者相关关系很高, 而在1963~1975和1992~2000年两时段内, 两者相关关系较差. 相似文献
3.
北极海冰的急剧消融在近年来欧亚大陆频发的低温事件中扮演着关键角色.秋季北极海冰的偏少对应着冬季欧亚大陆的低温天气,然而二者的联系在年代际和年际两种时间尺度上存在显著区别.本文运用1979—2012年哈德莱中心第一套海冰覆盖率(HadISST1)、欧洲中心(ERA_Interim)的2m温度、风场、海平面气压场、高度场等资料,分别研究了年代际和年际时间尺度上前期秋季北极海冰与欧亚冬季气温的联系.结果表明,欧亚和北极地区(0°—160°E,15°N—90°N)的冬季气温具有显著的年代际和年际变化.在年代际尺度上,温度异常分布在21世纪初由北极冷-大陆暖转为北极暖-大陆冷.这一年代际转折与前期秋季整个北极地区的海冰年代际减少联系密切.秋季北极全区海冰年代际偏少对应冬季欧亚大陆中高纬地区的高压异常,有利于北大西洋的暖湿气流北上和北极的冷空气南侵,造成北极暖-大陆冷的温度分布;在年际时间尺度上,温度异常分布主要由第一模态的年际变化部分和第二模态组成,且第一模态包含的年际变率信号也存在显著的年代际变化.年际尺度上全区北极海冰对欧亚冬季气温的影响远不及位于北冰洋西南边缘的巴伦支海、喀拉海和拉普捷夫海西部(30°E—120°E,75°N—85°N)的关键区海冰影响显著.关键区内海冰的偏少会引发冬季的北大西洋涛动负位相,导致北大西洋吹往欧亚大陆的暖湿气流减弱和欧亚大陆中高纬地区的气温偏低. 相似文献
4.
本文分析了由中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室(LASG/IAP)最新发展的FGOALS-g快速耦合模式300 a积分模拟结果,通过与多种观测资料的对比分析,讨论了北太平洋年代际变率的时空结构、主要年代际模态的演变特征以及与ENSO的联系等研究内容. 结果表明:该模式能成功模拟出北太平洋年代际变率的主要空间分布特征;模拟的年代际模态具有多时间尺度性,其中最显著的是周期约为10~20 a左右的准20年振荡模态,该模态上层海洋热容量异常的演变过程主要表现为大致沿副热带海洋涡旋做海盆尺度顺时针旋转的特征,相应的大气异常不仅与阿留申低压的变异有关,而且与太平洋-北美PNA)遥相关型以及上游的欧亚大气环流异常有密切关系;模拟的北太平洋年代际变率对年际ENSO循环的发生频率和强度有明显的调制作用. 但模拟的KOE区和阿拉斯加湾SST异常振幅比观测偏强,这与模式海冰偏多、高纬度SST偏冷的误差有关. 相似文献
5.
利用美国NCEP再分析月平均资料及我国华北地区26个测站月降水资料,采用奇异值分解(SVD)方法,研究了华北降水的年代际和年际变化特征与北半球大气环流的联系.结果表明,首先对降水和大气变量资料作相应时间尺度的分离是非常必要的,否则所得到的SVD结果不能反映年代际变化特征而只能反映年际变化特征;华北降水年代际和年际变化对应的大气环流异常有明显的差异;对应发生在20世纪70年代后期华北降水的一次年代际跃变,环流场均存在明显的跃变,而且有一个从地面向对流层上层传播的过程. 相似文献
6.
观测事实揭示,春季Hadley环流在年际时间尺度上与东亚夏季风环流和降水具有密切联系.在未来全球变暖背景下,春季Hadley环流与东亚夏季风环流和降水的这种年际关系是否会发生变化?针对该问题,本文在评估的基础上选取五个气候模式,分析了A1B排放情景下春季北半球Hadley环流年际变率的未来变化及其与东亚夏季风环流和降水的年际关系.多模式集合(MME)预估结果表明,在全球变暖背景下,与20世纪末期(1970—1999年)相比,到21世纪末期(2070—2099年),春季北半球Hadley环流的年际变率强度将减弱,减弱幅度达32%.随着春季Hadley环流年际变率的减弱,其与夏季西太平洋副热带高压和东亚夏季风强度的联系将变弱.MME模拟结果还显示,春季Hadley环流与夏季东亚西风急流和降水的关系也降低,但各单个模式间存在较大差异. 相似文献
7.
本文分析了由中国科学院大气物理研究所大气科学和地球流体力学数值模拟国家重点实验室(LASG/IAP)最新发展的FGOALS-g快速耦合模式300 a积分模拟结果,通过与多种观测资料的对比分析,讨论了北太平洋年代际变率的时空结构、主要年代际模态的演变特征以及与ENSO的联系等研究内容. 结果表明:该模式能成功模拟出北太平洋年代际变率的主要空间分布特征;模拟的年代际模态具有多时间尺度性,其中最显著的是周期约为10~20 a左右的准20年振荡模态,该模态上层海洋热容量异常的演变过程主要表现为大致沿副热带海洋涡旋做海盆尺度顺时针旋转的特征,相应的大气异常不仅与阿留申低压的变异有关,而且与太平洋-北美PNA)遥相关型以及上游的欧亚大气环流异常有密切关系;模拟的北太平洋年代际变率对年际ENSO循环的发生频率和强度有明显的调制作用. 但模拟的KOE区和阿拉斯加湾SST异常振幅比观测偏强,这与模式海冰偏多、高纬度SST偏冷的误差有关. 相似文献
8.
众多研究表明,太平洋年代际振荡(PDO)与东亚季风以及我国气候的年代际异常存在显著影响,然而其影响途径及机制仍不明确.本文分别分析了年代际尺度上的太平洋年代际振荡(PDO)、南北半球际大气质量振荡(IHO)以及东亚季风的变化特征,据此建立了三者之间的关系,并进一步分析了它们对我国东部冬夏两季年代际气候异常的影响,所得主要结果包括:(1)PDO与IHO以及东亚季风强度具有明显的年代际波动特征,三者之间存在较好联系,其中它们在70年代和90年代后期处于负位相,而在80年代至90年代中期均处于正位相期.PDO和IHO对全球大范围的低层气温异常,以及大气质量迁移尤其是东半球30°S-50°N区域的质量变化具有显著并且空间一致的影响;(2)当PDO为正位相时,整层大气质量年代际异常呈偶极型的自东半球向西半球太平洋区域输出,造成了南北半球际以及海陆间大气质量迁移,同时引起Walker环流的上升和下沉支位置变化,以及越赤道大气质量流的向北异常输送,并由此建立起东亚季风与PDO和IHO之间的联系;(3)PDO年代际异常与冬夏季节蒙古地区地表气压变动存在密切联系.当PDO指数增强时,冬夏季850hPa均出现显著反气旋风场异常,并在我国东部形成异常北风,从而显著影响东亚冬夏季风强度变化.与之对应,PDO指数与我国东部大部分地区的站点气温、降水的年代际分量保持显著的同期相关. 相似文献
9.
在热带太平洋,观测数据表明海表叶绿素(Chl)表现出年际尺度变率和由热带不稳定波(TIW)引发的中小尺度扰动这两者的共存现象;两者通过海洋生物引发的加热(OBH)反馈对ENSO造成的联合影响尚未得到充分的表征和理解.本文利用一个混合型大气-海洋物理-生物地球化学耦合模式(HCM AOPB)来量化年际和TIW尺度上Chl扰动对ENSO的单独以及联合调制影响. HCM敏感性试验结果证实了两者对ENSO振幅存在相反的作用,其中大尺度Chl年际变率造成的海洋生物-气候反馈效应通过其对上层海洋层结和垂向混合的影响来减弱ENSO,而TIW尺度的Chl扰动则倾向于增强ENSO.气候模式中ENSO的模拟敏感地依赖于对不同尺度上Chl效应的表征方式,因此有必要在气候模式模拟中充分地考虑不同尺度上Chl引发的气候效应.本文揭示了热带太平洋Chl效应是气候模式中ENSO模拟的一个偏差源,可为不同尺度上热带太平洋气候系统与海洋生态系统间相互作用提供新的见解.这些结果也揭示了ENSO调制的复杂性:即热带太平洋海洋生物地球化学过程相关的年际和TIW尺度上的Chl扰动与物理过程间的相互作用可对ENSO产生协同效应. 相似文献
10.
新疆北部汛期(7~8月)降水量具有明显的年际和年代际变化.针对年代际、除去年代际后年际和不同年代际背景下年际变化三种时间尺度,利用NECP/NCAR再分析资料,分析相应的大气环流.结果表明,三种时间尺度降水变化的物理机制不同,年代际背景非常重要.新疆北部汛期降水异常时,欧亚中高纬环流系统具有相当正压结构的显著异常.从气候角度和年代际大气环流变化,提出新疆年代际增湿存在索马里越赤道急流到新疆的三段式水汽接力输送方式,索马里急流和热带印度洋是中亚和新疆的重要水汽补充源之一. 相似文献
11.
Interannual climate variability in South America: impacts on seasonal precipitation, extreme events, and possible effects of climate change 总被引:8,自引:7,他引:1
Interannual variability is an important modulator of synoptic and intraseasonal variability in South America. This paper seeks
to characterize the main modes of interannual variability of seasonal precipitation and some associated mechanisms. The impact
of this variability on the frequency of extreme rainfall events and the possible effect of anthropogenic climate change on
this variability are reviewed. The interannual oscillations of the annual total precipitation are mainly due to the variability
in austral autumn and summer. While autumn is the dominant rainy season in the northern part of the continent, where the variability
is highest (especially in the northeastern part), summer is the rainy season over most of the continent, thanks to a summer
monsoon regime. In the monsoon season, the strongest variability occurs near the South Atlantic Convergence Zone (SACZ), which
is one of the most important features of the South American monsoon system. In all seasons but summer, the most important
source of variability is ENSO (El Ni?o Southern Oscillation), although ENSO shows a great contribution also in summer. The
ENSO impact on the frequency of extreme precipitation events is also important in all seasons, being generally even more significant
than the influence on seasonal rainfall totals. Climate change associated with increasing emission of greenhouse gases shows
potential to impact seasonal amounts of precipitation in South America, but there is still great uncertainty associated with
the projected changes, since there is not much agreement among the models’ outputs for most regions in the continent, with
the exception of southeastern South America and southern Andes. Climate change can also impact the natural variability modes
of seasonal precipitation associated with ENSO. 相似文献
12.
Spatio-temporal analysis of daily,seasonal and annual precipitation concentration in Jharkhand state,India 总被引:1,自引:0,他引:1
Nowadays, climate change and global warming have led to changes in the distribution of precipitation, which affect on the availability of water resources. Therefore, investigating the temporal and spatial variations of precipitation in the previous period is highly important in the future planning for flood control and local management of water resources. Considering the importance of this issue, in the present study, the precipitation concentration indices have been used for analysing precipitation changes at daily, seasonal, and annual time scales in the period of 1971 to 2011 over the Jharkhand state, India. Also, Modified Mann–Kendall test has used to study the trend of precipitation concentration indices in annual and seasonal time scales. The result shows a highly irregular and non-uniform distribution in the annual scale. For the seasonal scale an irregular and non-uniform distribution has been also observed, although the summer had a better situation than other seasons. For daily scale, none of the stations had a regular concentration and in the northeast and southern parts of the study area, there have been more irregularities. Furthermore, the results of investigating annual precipitation trend showed a combination of increasing and decreasing trend over the study area. The results of this study can be applied to manage water supplies, drainage projects, construct collection structures of urban flood, develop plans to prevent soil erosion, and designing appropriate plans to cope with drought conditions. 相似文献
13.
Abstract Characterization of the seasonal and inter-annual spatial and temporal variability of rainfall in a changing climate is vital to assess climate-induced changes and suggest adequate future water resources management strategies. Trends in annual, seasonal and maximum 30-day extreme rainfall over Ethiopia are investigated using 0.5° latitude?×?0.5° longitude gridded monthly precipitation data. The spatial coherence of annual rainfall among contiguous rainfall grid points is also assessed for possible spatial similarity across the country. The correlation between temporally coinciding North Atlantic Multidecadal Oscillation (AMO) index and annual rainfall variability is examined to understand the underlying coherence. In total 381 precipitation grid points covering the whole of Ethiopia with five decades (1951–2000) of precipitation data are analysed using the Mann-Kendall test and Moran spatial autocorrelation method. Summer (July–September) seasonal and annual rainfall data exhibit significant decreasing trends in northern, northwestern and western parts of the country, whereas a few grid points in eastern areas show increasing annual rainfall trends. Most other parts of the country exhibit statistically insignificant trends. Regions with high annual and seasonal rainfall distribution exhibit high temporal and spatial correlation indices. Finally, the country is sub-divided into four zones based on annual rainfall similarity. The association of the AMO index with annual rainfall is modestly good for northern and northeastern parts of the country; however, it is weak over the southern region. Editor Z.W. Kundzewicz; Associate editor S. Uhlenbrook Citation Wagesho, N., Goel, N.K., and Jain, M.K. 2013. Temporal and spatial variability of annual and seasonal rainfall over Ethiopia. Hydrological Sciences Journal, 58 (2), 354–373. 相似文献
14.
利用近50年华北地区26个站逐月降水观测资料和全球大气海洋分析资料,分析了华北降水的年代际变化特征及其和全球海气系统年代际变化的关系.对华北降水距平指数变化分析表明,近50年来华北降水具有减少的总体趋势,叠加在该趋势之上的是年代际变化,其中1965年和1980年发生了两次跃变,使得20世纪80年代干旱尤为严重.在对华北地区降水年代际变化特征分析的基础上,揭示了与华北降水年代际异常相伴随的大气环流和上层海洋热力异常型.结果表明,华北降水年代际异常与太平洋上层海洋热力状况异常有显著关系,主要表现为太平洋年代际振荡(PDO)与华北降水异常的相关.在年代际时间尺度上,华北干旱与上层海洋热力及大气环流异常的配置关系如下:当华北地区干旱时,则热带中东太平洋海温偏高,北太平洋中部海温偏低,即太平洋上主要表现为PDO暖位相,全球大部分地区(包括华北地区)气温偏高,青藏高原地区气温偏低,日本北部及东西伯利亚气压异常偏低,华北及其以南大片地区气压偏高,华北地区由异常西北风控制,不利于水汽向华北地区输送. 相似文献
15.
Heinz Wanner Stefan Brönnimann Carlo Casty Dimitrios Gyalistras Jürg Luterbacher Christoph Schmutz David B. Stephenson Eleni Xoplaki 《Surveys in Geophysics》2001,22(4):321-381
This paper aims to provide a comprehensive review of previous studies and concepts concerning the North Atlantic Oscillation. The North Atlantic Oscillation (NAO) and its recent homologue, the Arctic Oscillation/Northern Hemisphere annular mode (AO/NAM), are the most prominent modes of variability in the Northern Hemisphere winter climate. The NAO teleconnection is characterised by a meridional displacement of atmospheric mass over the North Atlantic area. Its state is usually expressed by the standardised air pressure difference between the Azores High and the Iceland Low. ThisNAO index is a measure of the strength of the westerly flow (positive with strong westerlies, and vice versa). Together with the El Niño/Southern Oscillation (ENSO) phenomenon, the NAO is a major source of seasonal to interdecadal variability in the global atmosphere. On interannual and shorter time scales, the NAO dynamics can be explained as a purely internal mode of variability of the atmospheric circulation. Interdecadal variability maybe influenced, however, by ocean and sea-ice processes. 相似文献
16.
基于24个CMIP5全球耦合模式模拟结果,分析了中国区域年平均降水和ETCCDI强降水量(R95p)、极端强降水量(R99p)对增暖的响应.定量分析结果显示,CMIP5集合模拟的当代中国区域平均降水对增温的响应较观测偏弱,而极端降水的响应则偏强.对各子区域气温与平均降水、极端降水的关系均有一定的模拟能力,并且极端降水的模拟好于平均降水.RCP4.5和RCP8.5情景下,随着气温的升高,中国区域平均降水和极端降水均呈现一致增加的趋势,中国区域平均气温每升高1℃,平均降水增加的百分率分别为3.5%和2.4%,R95p增加百分率为11.9%和11.0%,R99p更加敏感,分别增加21.6%和22.4%.就各分区来看,当代的区域性差异较大,未来则普遍增强,并且区域性差异减小,在持续增暖背景下,中国及各分区极端降水对增暖的响应比平均降水更强,并且越强的极端降水敏感性越大.未来北方地区平均降水对增暖的响应比南方地区的要大,青藏高原和西南地区的R95p和R99p增加最显著,表明未来这些区域发生暴雨和洪涝的风险将增大. 相似文献
17.
An analysis of the climate change signal for seasonal temperature and precipitation over the Northern Adriatic region is presented here. We collected 43 regional climate simulations covering the target area, including experiments produced in the context of the PRUDENCE and ENSEMBLES projects, and additional experiments produced by the Swedish Meteorological and Hydrological Institute. The ability of the models to simulate the present climate in terms of mean and interannual variability is discussed and the insufficient reproduction of some features, such as the intensity of summer precipitation, are shown. The contribution to the variance associated with the intermodel spread is computed. The changes of mean and interannual variability are analyzed for the period 2071–2100 in the PRUDENCE runs (A2 scenario) and the periods 2021–2050 and 2071–2100 (A1B scenario) for the other runs. Ensemble results show a major warming at the end of the 21st century. Warming will be larger in the A2 scenario (about 5.5 K in summer and 4 K in winter) than in the A1B. Precipitation is projected to increase in winter and decrease in summer by 20% (+0.5 mm/day and −1 mm/day over the Alps, respectively). The climate change signal for scenario A1B in the period 2021–2050 is significant for temperature, but not yet for precipitation. In summer, interannual variability is projected to increase for temperature and for precipitation. Winter interannual variability change is different among scenarios. A reduction of precipitation is found for A2, while for A1B a reduction of temperature interannual variability is observed. 相似文献
18.
Transpiration is an important component of soil water storage and stream‐flow and is linked with ecosystem productivity, species distribution, and ecosystem health. In mountain environments, complex topography creates heterogeneity in key controls on transpiration as well as logistical challenges for collecting representative measurements. In these settings, ecosystem models can be used to account for variation in space and time of the dominant controls on transpiration and provide estimates of transpiration patterns and their sensitivity to climate variability and change. The Regional Hydro‐Ecological Simulation System (RHESSys) model was used to assess elevational differences in sensitivity of transpiration rates to the spatiotemporal variability of climate variables across the Upper Merced River watershed, Yosemite Valley, California, USA. At the basin scale, predicted annual transpiration was lowest in driest and wettest years, and greatest in moderate precipitation years (R2 = 0·32 and 0·29, based on polynomial regression of maximum snow depth and annual precipitation, respectively). At finer spatial scales, responsiveness of transpiration rates to climate differed along an elevational gradient. Low elevations (1200–1800 m) showed little interannual variation in transpiration due to topographically controlled high soil moistures along the river corridor. Annual conifer stand transpiration at intermediate elevations (1800–2150 m) responded more strongly to precipitation, resulting in a unimodal relationship between transpiration and precipitation where highest transpiration occurred during moderate precipitation levels, regardless of annual air temperatures. Higher elevations (2150–2600 m) maintained this trend, but air temperature sensitivities were greater. At these elevations, snowfall provides enough moisture for growth, and increased temperatures influenced transpiration. Transpiration at the highest elevations (2600–4000 m) showed strong sensitivity to air temperature, little sensitivity to precipitation. Model results suggest elevational differences in vegetation water use and sensitivity to climate were significant and will likely play a key role in controlling responses and vulnerability of Sierra Nevada ecosystems to climate change. Copyright © 2008 John Wiley & Sons, Ltd. 相似文献