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1.
北半球温带气旋活动和风暴路径的年代际变化 总被引:12,自引:3,他引:9
基于欧洲中心再分析数据ERA40的海平面气压场和高度场,本文分别采用拉格朗日和欧拉方法研究分析了1958~2001年北半球的不同季节温带气旋活动和风暴路径的年代际变化,以及可能的原因.以客观判定和追踪温带气旋为基础的拉格朗日方法得到了北半球的两个温带气旋主要活动中心,即北太平洋地区和北大西洋/北美地区,同时以500 hPa位势高度天气尺度滤波方差为基础的欧拉方法得到了同主要气旋活动中心相吻合的两条风暴轴.研究表明,44年中北大西洋/北美地区温带气旋活动北移加强,以春季最为显著.风暴轴也同样存在着向极移动并加强的特征,并且温带气旋和风暴路径两者移动趋势的相关性很高.作为一个典型地区,北大西洋/北美地区的气旋活动体现了风暴路径的北移,以及温带地区向极地的扩展.但有意思的是北太平洋的情况完全不同,即北太平洋地区的温带气旋活动和风暴轴向低纬度偏移并加强,以春季的南移趋势最为显著.对于此结论,两种方法也有很高的统计相关性.虽然大量研究表明北半球整体上呈现出风暴路径北移的变化特征,但对于具体地区情况有明显差异.另外,400 hPa最大Eady增长率和气旋活动频率的经验正交展开函数 (EOF) 第一模态的空间分布和时间序列非常相似,北太平洋地区和北大西洋地区风暴路径相反的变化趋势很可能同其大气斜压性的同位相的变化有着密切的关系.这也从另一个方面支持了本文对温带气旋和风暴路径年代际变化的分析. 相似文献
2.
利用1953-2007年NCEP/NCAR再分析逐日海平面气压场资料,统计分析东亚地区北方气旋和南方气旋的时间和地域分布特征。结果表明:南、北气旋活动频数存在明显的年际和年代际变化,伴随着一次全球性的年代际气候跃变,20世纪80年代初期北方气旋活动频数出现了显著的突变。从月际分布可知,5月北方气旋频数最多,8月南方气旋频数最多;春季北方气旋活动频繁,存在着明显的两个高值中心,分另Ij位于蒙古国中部和中国东北地区北部;夏季南方气旋活动频繁,主要集中在中国东部沿海及日本南部海面。南北气旋活动频数的季节变化与大气环流的变化密切相关。相关统计结果可增加对东亚温带气旋活动规律的认识和了解,并为预测和预报提供参考。 相似文献
3.
进入北极地区的气旋在移动过程中往往伴有大风、强降水等特征,对北极气候变化有深刻的影响。基于NCEP2再分析资料,识别并跟踪了北半球夏季(6—8月)从中纬度进入北极的温带气旋,考察了其年际变化特征和影响因素。结果表明:1979—2019年夏季进入北极的温带气旋共867个,其中消失在北极边缘区域和中心区域的数量分别为688个和161个,且后者平均强度更大、平均持续时间更长。分区域研究发现,夏季从陆地进入极区的气旋个数较多,而从海洋进入极区的气旋强度更大,活动更为剧烈。对进入北极的气旋年际时间序列进行分析发现,夏季进入北极的气旋个数和强度均存在年际变率,其中气旋个数的年际变率尤为显著。气旋个数年际变率主要周期为5 a,强度的主要周期约为2.7 a。进一步分析发现,引导气流是影响气旋向北移动的重要因素。此外,夏季北大西洋气旋强度与同期北大西洋涛动(North Atlantic Oscillation,NAO)指数存在较好相关。研究还表明,进入极区气旋活动的年际变化受大气斜压不稳定性的影响,在北太平洋地区区域平均的Eady增长率与气旋个数和强度的相关性均最强,相关系数分别为0.4和0.5。 相似文献
4.
陆面热力异常与东亚夏季中纬度气旋年代际变化的联系 总被引:1,自引:0,他引:1
基于欧洲中期预报中心的再分析数据ERA-interim,利用统计学方法分析了1979—2013年期间东亚中纬度地区气旋生成频率和陆面热力异常的年代际变化及两者的可能联系。结果表明,东亚中纬度地区存在气旋活动频繁的气旋源地,该地区的温带气旋生成频率具有明显的年代际变化,1990年之前气旋生成频率偏多,1990s至今偏少,而且东亚中纬度地区陆面热力异常的变化有明显的年代际增暖信号;进一步的分析发现,东亚夏季中纬度气旋活动的年代际变化与陆面异常异常之间存在密切的联系,东亚中纬度地区陆面年代际增暖,是引起温度气旋活动年代际减弱的一个重要原因。由于陆面增暖的非均匀性,在50°N以北存在一个影响中纬度气旋生成频率的关键区,关键区陆面的年代际异常增暖,导致气旋源地温度经向梯度减弱,大气斜压性随之减弱,从而使得气旋生成频率年代际减少。 相似文献
5.
利用 CMIP5(Coupled Model Intercomparison Project Phase 5)的6个气候耦合模式中等排放情景———RCP4?5(典型浓度路径4?5)下的模拟结果对北半球温带气旋数目、风暴路径和强度的未来变化进行了研究分析。结果表明:(1)相对于20世纪后半叶,RCP4?5情景下的2053—2100年,虽然各模式的模拟结果存在一定的区域性差异,但共同显示了至21世纪末北半球整体温带气旋生成将减少,较低纬度减少得更显著。(2)模式较一致地模拟出未来北半球温带气旋的中心气压有降低的趋势,涡度强度将线性减弱。大多数的模式模拟得到北大西洋风暴轴未来将继续向极地偏移,但强度主要将减弱;过半的模式显示北太平洋风暴轴也将向极地偏移,强度变化则随季节的不同而不同。(3)6个模式的模拟结果均显示对流层中高层斜压区未来将向高层和高纬度扩展,南半球的变化更为显著。斜压区的变化在某种程度上反映了风暴轴的类似变化,因此, 这也支持了北太平洋和北大西洋风暴路径未来可能向极地偏移的结论。RCP4?5情景下北半球整体温带气旋活动将显著减少,但斜压区和风暴轴向高纬度的偏移将使较低纬度未来温带气旋活动减少得更为显著。 相似文献
6.
西北太平洋热带气旋气候变化的若干研究进展 总被引:13,自引:11,他引:2
热带气旋气候变化研究不仅是当前国际热带气旋气候界的热点科学问题,而且也是具有现实意义的社会问题,各国气象学者和科学家们对此进行了广泛的研究。虽然热带气旋活动与气候变化之间的关系及其相应的内在物理机制至今还处在探究之中,但是近20多年来热带气旋气候学的研究还是取得了显著的进展。本文主要针对濒临中国的西北太平洋海域,回顾了热带气旋活动季节内、年际、年代际变化及其全球变暖背景下的变化趋势的气候学研究。此外,文中也对西北太平洋热带气旋气候学的研究进行了展望,并提出了该领域中一些亟待解决的科学问题。 相似文献
7.
自20世纪70年代末期以来,西北太平洋的热带气旋在全球变暖的背景下主要发生了两种宏观的气候变化:一个是热带气旋生成频数呈现年代际减少,尤其是在东南部海域;另一个则是其生成与活动位置等总体特征有向西北偏移的趋势。本文对这两个方面的研究进展进行了概述。近些年的研究表明,垂直风切变的增强可能是夏秋季热带气旋频数减少的最主要原因,这与太平洋-印度洋海面温度变化导致的大尺度环境变化有密切联系。同样有研究认为北大西洋海面温度的多年代际振荡对近期西北太平洋热带气旋生成频数的减少也非常重要。但西北太平洋西部强热带气旋的频数呈现出增加的趋势,这可能与东亚近海海面温度的显著升高有关,尽管这种变化是否可信仍有争议。近20年来,西北太平洋热带气旋活动普遍出现西北移倾向,包括生成位置和路径位置,这种变化可能受到了ENSO变异及20世纪90年代末期太平洋气候突变的调控。同时,热带环流的极向扩张又导致了热带气旋的有利环境向北扩张,因此西北太平洋热带气旋活动也出现极向迁移的趋势。 相似文献
8.
近50 a春季东亚温带气旋活动频数的气候特征及其变化 总被引:14,自引:1,他引:14
根据1948-2000年共53 a的NCEP/NCAR逐日海平面气压再分析资料,分析了春季(3、4、5月)东亚内陆和沿海地区气旋活动频数、气旋移动路径等气候特征及其年际、年代际变化,结果表明在春季的3、4、5月份中,内陆存在三个明显的气旋活动频数较大的地区,分别位于101°E、45°N附近的蒙古高压南缘、贝加尔湖以东的115°E、53°N附近地区和126°E、53°N我国东北北部附近地区.蒙古地区春季气旋活动频数存在明显的年代际变化,50年代气旋活动频数较少,60年代开始到70年代后期气旋活动频数较多,从70年代末至今又进入一个气旋活动频数较少的时期.贝加尔湖东部地区在50年代初气旋活动频数较多,50年代中期到60年代中期气旋活动频数较少,而60年代后期到70年代后期气旋活动频数又较多,此后气旋活动频数逐渐减少.我国东北地区春季各月气旋活动频数没有明显的年代际变化,只有80年代以来气旋活动频数的振幅较大.东亚沿海春季气旋活动频数较高的地区主要位于我国东北到俄罗斯远东和我国长江中下游到日本一带.从气旋活动路径来看,我国长江中下游到日本一带气旋活动路径在各个年代基本相同,没有明显的年代际变化,而我国东北到俄罗斯远东地区气旋活动路径在不同年代略有差异.进一步分析发现,气旋活动频数与北方地区春季降水量及沙尘暴发生次数具有一定关系. 相似文献
9.
本文主要综述和回顾了近年来季风系统研究中心关于西北太平洋热带气旋和台风(TCs)活动的气候学研究进展及有关的国内外研究.文中不仅回顾了最近关于夏、秋季西北太平洋利于TCs生成的大尺度环流型及其与涡旋的正压能量交换、西北太平洋TCs活动的年际和年代际及季节内的变化特征、以及今后全球变暖背景下西北太平洋TCs活动的变化趋势的气候学研究进展,而且综述了西北太平洋季风槽及热带对流耦合波动对西北太平洋上TCs生成的动力作用的研究.此外,文中还指出今后有关西北太平洋TCs活动一些亟需进一步研究的气候学问题. 相似文献
10.
11.
Climatology and interannual variations of wintertime extratropical cyclone frequency in CCSM3 twentieth century simulation
are compared with the NCEP/NCAR reanalysis during 1950–1999. CCSM3 can simulate the storm tracks reasonably well, although
the model produces slightly less cyclones at the beginning of the Pacific and Atlantic storm tracks and weaker poleward deflection
over the Pacific. As in the reanalysis, frequency of cyclones stronger than 980 hPa shows significant correlation with the
Pacific/North America (PNA) teleconnection pattern over the Pacific region and with the North Atlantic Oscillation (NAO) in
the Atlantic sector. Composite maps are constructed for opposite phases of El Nino-Southern Oscillation (ENSO) and the NAO
and all anomalous patterns coincide with observed. One CCSM3 twenty-first century A1B scenario realization indicates there
is significant increase in the extratropical cyclone frequency on the US west coast and decrease in Alaska. Meanwhile, cyclone
frequency increases from the Great Lakes region to Quebec and decreases over the US east coast, suggesting a possible northward
shift of the Atlantic storm tracks under the warmer climate. The cyclone frequency anomalies are closely linked to changes
in seasonal mean states of the upper-troposphere zonal wind and baroclinicity in the lower troposphere. Due to lack of 6-hourly
outputs, we cannot apply the cyclone-tracking algorithm to the other eight CCSM3 realizations. Based on the linkage between
the mean state change and the cyclone frequency anomalies, it is likely a common feature among the other ensemble members
that cyclone activity is reduced on the East Coast and in Alaska as a result of global warming. 相似文献
12.
Northern Hemisphere winter storm tracks are a key element of the winter weather and climate at mid-latitudes. Before projections of climate change are made for these regions, it is necessary to be sure that climate models are able to reproduce the main features of observed storm tracks. The simulated storm tracks are assessed for a variety of Hadley Centre models and are shown to be well modelled on the whole. The atmosphere-only model with the semi-Lagrangian dynamical core produces generally more realistic storm tracks than the model with the Eulerian dynamical core, provided the horizontal resolution is high enough. The two models respond in different ways to changes in horizontal resolution: the model with the semi-Lagrangian dynamical core has much reduced frequency and strength of cyclonic features at lower resolution due to reduced transient eddy kinetic energy. The model with Eulerian dynamical core displays much smaller changes in frequency and strength of features with changes in horizontal resolution, but the location of the storm tracks as well as secondary development are sensitive to resolution. Coupling the atmosphere-only model (with semi-Lagrangian dynamical core) to an ocean model seems to affect the storm tracks largely via errors in the tropical representation. For instance a cold SST bias in the Pacific and a lack of ENSO variability lead to large changes in the Pacific storm track. Extratropical SST biases appear to have a more localised effect on the storm tracks. 相似文献
13.
Changes in storm tracks and energy transports in a warmer climate simulated by the GFDL CM2.1 model 总被引:1,自引:0,他引:1
Yutian Wu Mingfang Ting Richard Seager Huei-Ping Huang Mark A. Cane 《Climate Dynamics》2011,37(1-2):53-72
Storm tracks play a major role in regulating the precipitation and hydrological cycle in midlatitudes. The changes in the location and amplitude of the storm tracks in response to global warming will have significant impacts on the poleward transport of heat, momentum and moisture and on the hydrological cycle. Recent studies have indicated a poleward shift of the storm tracks and the midlatitude precipitation zone in the warming world that will lead to subtropical drying and higher latitude moistening. This study agrees with this key feature for not only the annual mean but also different seasons and for the zonal mean as well as horizontal structures based on the analysis of Geophysical Fluid Dynamics Laboratory (GFDL) CM2.1 model simulations. Further analyses show that the meridional sensible and latent heat fluxes associated with the storm tracks shift poleward and intensify in both boreal summer and winter in the late twenty-first century (years 2081?C2100) relative to the latter half of the twentieth century (years 1961?C2000). The maximum dry Eady growth rate is examined to determine the effect of global warming on the time mean state and associated available potential energy for transient growth. The trend in maximum Eady growth rate is generally consistent with the poleward shift and intensification of the storm tracks in the middle latitudes of both hemispheres in both seasons. However, in the lower troposphere in northern winter, increased meridional eddy transfer within the storm tracks is more associated with increased eddy velocity, stronger correlation between eddy velocity and eddy moist static energy, and longer eddy length scale. The changing characteristics of baroclinic instability are, therefore, needed to explain the storm track response as climate warms. Diagnosis of the latitude-by-latitude energy budget for the current and future climate demonstrates how the coupling between radiative and surface heat fluxes and eddy heat and moisture transport influences the midlatitude storm track response to global warming. Through radiative forcing by increased atmospheric carbon dioxide and water vapor, more energy is gained within the tropics and subtropics, while in the middle and high latitudes energy is reduced through increased outgoing terrestrial radiation in the Northern Hemisphere and increased ocean heat uptake in the Southern Hemisphere. This enhanced energy imbalance in the future climate requires larger atmospheric energy transports in the midlatitudes which are partially accomplished by intensified storm tracks. Finally a sequence of cause and effect for the storm track response in the warming world is proposed that combines energy budget constraints with baroclinic instability theory. 相似文献
14.
Based on the Joint Typhoon Warning Center (JTWC) best-track dataset between 1965 and 2009 and the characteristic parameters including tropical cyclone (TC) position, intensity, path length and direction, a method for objective classification of the Northwestern Pacific tropical cyclone tracks is established by using K-means Clustering. The TC lifespan, energy, active season and landfall probability of seven clusters of tropical cyclone tracks are comparatively analyzed. The characteristics of these parameters are quite different among different tropical cyclone track clusters. From the trend of the past two decades, the frequency of the western recurving cluster (accounting for 21.3% of the total) increased, and the lifespan elongated slightly, which differs from the other clusters. The annual variation of the Power Dissipation Index (PDI) of most clusters mainly depended on the TC intensity and frequency. However, the annual variation of the PDI in the northwestern moving then recurving cluster and the pelagic west-northwest moving cluster mainly depended on the frequency. 相似文献
15.
Response of Northern Hemisphere storm tracks to Indian-western Pacific Ocean warming in atmospheric general circulation models 总被引:1,自引:1,他引:0
With 40 years integration output of two atmospheric general circulation models (GAMIL/IAP and HadAM3/UKMO) forced with identical prescribed seasonally-varying sea surface temperature, this study examines the effect of the observed Indian-western Pacific Ocean (IWP) warming on the Northern Hemisphere storm tracks. Both models indicate that the observed IWP warming tends to cause both the North Pacific storm track (NPST) and the North Atlantic storm track (NAST) to move northward. Such a consistent effect on the two storm tracks is closely associated with the changes in the low-level atmospheric baroclinicity, high-level jet stream and upper-level geopotential height. The IWP warming can excite a wavelike circum-global teleconnection in the geopotential height that gives rise to an anticyclonic anomaly over the midlatitude North Pacific and a positive-phase NAO anomaly over the North Atlantic. These geopotential height anomalies tend to enhance upper-level zonal westerly winds north of the climatological jet axes and increase low-level baroclinicity and eddy growth rates, thus favoring transient eddy more active north of the climatological storm track axes, responsible for the northward shift of the both storm tracks. The IWP warming-induced northward shift of the NAST is quite similar to the observed, suggesting that the IWP warming can be one of the key factors to cause decadal northward shift of the NAST since the 1980s. However, the IWP warming-induced northward shift of the NPST is completely opposite to the observed, implying that the observed southward shift of the NPST since the 1980s would be primarily attributed to other reasons, although the IWP warming can have a cancelling effect against those reasons. 相似文献
16.
Understanding the impact of climate change on Northern Hemisphere extra-tropical cyclones 总被引:3,自引:2,他引:1
Ruth E. McDonald 《Climate Dynamics》2011,37(7-8):1399-1425
Extra-tropical cyclones strongly influence weather and climate in mid-latitudes and any future changes may have large impacts on the local scale. In this study Northern Hemisphere storms are analysed in ensembles of time-slice experiments carried out with an atmosphere only model with present day and future anthropogenic emissions. The present day experiment is forced by observed sea-surface temperature and sea-ice. The sea-surface temperatures and sea-ice for the future experiment are derived by adding anomalies, from parallel but lower resolution coupled model experiments, to the observed data. The storms in the present day simulation compare fairly well with observations in all seasons but some errors remain. In the future simulations there is some evidence of a poleward shift in the storm tracks in some seasons and regions. There are fewer cyclones in the Northern Hemisphere in winter and spring. The northeast end of the North Atlantic storm track is shifted south in winter giving more storms and increased frequency of strong winds over the British Isles. This shift is related to an increase in baroclinicity and a southward shift of the jet that occurs as a response to a minimum in ocean warming in the central North Atlantic. An increase in the frequency of storms over the UK is likely to cause enhanced levels of wind and flood damage. These results concur with those from some other models, however, large uncertainties remain. 相似文献
17.
北太平洋风暴轴的三维空间结构 总被引:9,自引:1,他引:8
文中利用最新的0.5°×0.5°分辨率QuikSCAT(QuikBird Satellite Microwave Scatterometer Sea Winds Data)海面风场资料、NCEP(National Center for Environmental Prediction)的10 m高度风场资料和全球客观再分析资料,对1999-2005年冬季(1月)和夏季(7月)北太平洋风暴轴的三维空间结构进行了分析,发现冬季北太平洋风暴轴的强度较强,呈明显的纬向拉伸带状分布特征,位置偏南.夏季北太平洋风暴轴的强度较弱,位置偏北.根据不同高度上位势高度方差的水平分布特征,绘制了北太平洋风暴轴的三维结构示意图.利用高分辨率QuikSCAT资料对风暴轴特征的刻画更为细致,不但验证了Nakamu-ra在南大洋发现的双风暴轴现象,而且还发现在北太平洋和北大西洋下层分别存在"副热带风暴轴"和"副极地风暴轴"两个风暴轴.对1999-2005年冬季北太平洋气旋和反气旋的移动路径进行的统计分析,为北太平洋"双风暴轴"的存在提供了强有力的证据. 相似文献
18.
Extratropical cyclone variability in the Northern Hemisphere winter from the NCEP/NCAR reanalysis data 总被引:9,自引:0,他引:9
The winter climatology of Northern Hemisphere cyclone activity was derived from 6-hourly NCEP/NCAR reanalysis data for the
period from 1958 to 1999, using software which provides improved accuracy in cyclone identification in comparison to numerical
tracking schemes. Cyclone characteristics over the Kuroshio and Gulfstream are very different to those over continental North
America and the Arctic. Analysis of Northern Hemisphere cyclones shows secular and decadal-scale changes in cyclone frequency,
intensity, lifetime and deepening rates. The western Pacific and Atlantic are characterized by an increase in cyclone intensity
and deepening during the 42-year period, although the eastern Pacific and continental North America demonstrate opposite tendencies
in most cyclone characteristics. There is an increase of the number of cyclones in the Arctic and in the western Pacific and
a downward tendency over the Gulf Stream and subpolar Pacific. Decadal scale variability in cyclone activity over the Atlantic
and Pacific exhibits south-north dipole-like patterns. Atlantic and Pacific cyclone activity associated with the NAO and PNA
is analyzed. Atlantic cyclone frequency demonstrates a high correlation with NAO and reflects the NAO shift in the mid 1970s,
associated with considerable changes in European storm tracks. The PNA is largely linked to the eastern Pacific cyclone frequencies,
and controls cyclone activity over the Gulf region and the North American coast during the last two decades. Assessment of
the accuracy of the results and comparison with those derived using numerical algorithms, shows that biases inherent in numerical
procedures are not negligible.
Received: 7 July 2000 / Accepted: 30 November 2000 相似文献
19.
Using Joint Warning Typhoon Center (JTWC) best track data during the period 1948-2010, decadal and interdecadal changes of annual category 4 and 5 tropical cyclone (TC) frequency in the western North Pacific basin were examined. By allowing all of the observed TCs in the JTWC dataset to move along the observed TC tracks in a TC intensity model, the annual category 4 and 5 TC frequency was simulated. The results agreed well with observations when the TC intensity prior to 1973 was adjusted based on time-dependent biases due to changes in measurement and reporting practices. The simulated and adjusted time series showed significant decadal (12-18 years) variability, while the interdecadal (18-32 years) variability was found to be statistically insignificant. Numerical simulations indicated that changes in TC tracks are the most important factor for the decadal variability in the category 4 and 5 TC frequency in the western North Pacific basin, while a combined effect of changes in SST and vertical wind shear also contributes to the decadal variability. Further analysis suggested that the active phase of category 4 and 5 TCs is closely associated with an eastward shift in the TC formation locations, which allows more TCs to follow a longer journey, favoring the development of category 4 and 5 TCs. The active phase corresponds with the SST warming over the tropical central and eastern Pacific and the eastward extension of the monsoon trough, thus leading to the eastward shift in TC formation locations. 相似文献