共查询到19条相似文献,搜索用时 125 毫秒
1.
台风Matsa(2005)和Wipha(2007)变性过程对比分析 总被引:2,自引:0,他引:2
利用日本气象厅热带气旋年鉴资料和JRA-25再分析资料,对0509号台风Matsa和0712号台风Wipha变性过程进行了对比分析。结果表明,台风Matsa和Wipha均是在我国登陆后转向东北方向运动过程中发生变性,但Matsa嵌入中纬度高空锋区,变性为温带气旋后有再加强过程,而Wipha仅外围环流与锋区接触,变性为温带气旋后无再加强过程。通过等熵面位涡分析进一步表明,Matsa变性加强表现为高层正位涡与低层暖平流的耦合,以及高层正位涡下传至中低层;Wipha的变性过程中,高层正位涡并未与低层暖平流耦合,高层正位涡无明显的下传。 相似文献
2.
利用日本气象厅1979—2008年的热带气旋年鉴资料和JRA-25资料(日本25年再分析资料),对登陆中国的变性加强(IET)和变性减弱(WET)两类热带气旋(TC)的环境场进行动态合成分析,并计算其动能收支项。分析表明:(1) IET(WET)在强(弱)的高空槽以及高空急流的影响下,高层辐散增强、低层辐合增强(减弱),上升运动明显加强(微弱加强),相应的IET(WET)变性加强(减弱)。(2) 低层散度风动能制造的增加(减少)是IET(WET)变性后的低层气旋加强(减弱)的主要原因之一;低层散度风动能制造则与TC低层斜压锋区的发展密切相关。(3) IET(WET)受强(弱)的高空槽影响,高层旋转风动能制造相应增长(耗散),有利(不利)于其维持。 相似文献
3.
高空槽对9711号台风变性加强影响的数值研究 总被引:26,自引:9,他引:26
9711号台风Winnie是一个在中国大陆长久维持(2—3 d)并产生强降水的热带气旋(TC),在其深入内陆过程中变性加强为一个温带气旋。用MM5V3对不同强度高空槽影响下Winnie的变性加强过程进行了数值研究。结果表明:(1)Winnie变性加强过程表现为强锋面侵入台风内部、冷空气包裹台风中心、一个温带气旋在近地层锋面上强烈发展的过程;(2)Winnie在陆上的变性加强与西风带高空槽的强度密切相关。TC与不同强度高空槽相互作用过程中,较深槽携带较强冷平流、正涡度平流以及较强的槽前高空辐散,从而有利于TC的维持和变性发展。数值试验中,高空槽越强,Winnie变性加强越明显,温带气旋的发展越快;(3)模拟结果的位涡分析表明,Winnie的温带变性发展与对流层高层正位涡下传、低层锋区和TC低压环流三者之间的相互作用有关。 相似文献
4.
9711号台风Winnie和0010号台风Bills均在中国大陆发生变性,但前者变性后再度加强,而后者变性后减弱消亡。从湿位涡理论出发,对比分析两者的变性过程,结果表明:作为变性台风,Winnie和Bilis均在北上过程中与中纬度西风槽发生作用,但前者与高空槽发生耦合,后者仅接近高空槽底部,没有发生耦合;Winnie变性加强过程表现为一个温带气旋在低层锋区上的强烈发展过程,主要与高层正位涡扰动下传、低层锋区及热带气旋低压环流之间的相互作用有关。Pm湿斜压项增长引起的倾斜涡度发展是登陆热带气旋变性加强的主要因子。在Bills变性过程中,高层无明显的正位涡扰动下传,热带气旋低压环流内无锋区面出现,大气斜压性弱且变化不明显。 相似文献
5.
《气象与环境学报》2016,(3)
利用FY-2E卫星TBB资料、日本GMS卫星TBB资料及NCEP的1°×1°再分析资料对两次登陆后北上影响天津地区的热带气旋(0421号"海马"和1210号"达维")进行对比分析。结果表明:影响天津地区的两个热带气旋北上之后造成的降水呈不对称分布,分别发生在热带气旋"海马"中心北到西北侧(移动路径前方)和热带气旋"达维"中心东北侧,与动力条件(上升运动)和热力条件(暖平流)的不对称分布有关。两个热带气旋在北上过程中不同程度与西风槽产生相互作用,区别在于热带气旋"海马"遇到的高空槽比较深厚,与槽前偏南急流产生耦合作用,同时高空有高位涡下传至对流层低层,诱使地面气旋发展;而热带气旋"达维"遇到的高空槽比较弱,仅靠近高空槽底部,耦合作用不明显,高空也没有明显的正位涡下传至低层,不利于地面气旋的维持发展,导致热带气旋"海马"在登陆后减弱情况下又发展加强,而热带气旋"达维"则一直减弱直到消散在渤海海面。 相似文献
6.
通过对登陆台风Winnie(1997)的演变过程分析,发现登陆后的台风经历三个阶段:衰减阶段、变性阶段、重新加强阶段。其变性过程类似于Sekioka等人提出的复合型,变性后逐渐演变为Shapiro—Keyser气旋模型。通过对物理量的诊断分析发现,对流层中高层冷空气的下沉入侵以及对流层低层的暖平流是热带气旋变性的原因。冷空气的入侵使具有暖心结构的热带气旋演变为斜压结构的温带气旋。变性后气旋得到了重新发展,低层维持的较明显暖平流以及与高空急流相对应的散度区和高空涡度平流是导致气旋重新发展的重要物理因子。 相似文献
7.
选取西北太平洋上两个生命史中发生变性的热带气旋Yagi和Francisco,前者变性后有一个24小时的再增强过程,而后者则继续减弱直至消亡。利用日本气象厅提供的热带气旋资料和美国环境预报中心(NCEP)提供的FNL全球分析资料,对比分析两个TC在变性阶段的形势场,发现两者在高低层的环境场均具有明显的差异:Yagi在变性阶段其高空槽较强且在低层有一个与中纬度原先存在的温带气旋合并的过程;而Francisco在变性阶段其高空槽较弱,且变性后自行消亡。另外探讨了导致Yagi变性增强的原因,结果表明:(1)Yagi变性阶段与高空槽前的急流相互作用时,高空急流入口区左侧和出口区右侧的次级环流将产生高空辐散低空辐合的趋势,有利于低层TC低压的发展。同时,当Yagi在穿越急流的过程当中,垂直风切变的增加将导致斜压不稳定增强,低层锋区强烈发展,锋区内的斜压能量可能向TC动能转化,从而使得Yagi发展增强;(2)高空槽所对应的高层湿位涡下传可使得低层正涡度增长,从而在低层诱生出气旋性环流,有利于Yagi变性后重新发展;(3)Yagi与中纬度原先存在的温带气旋发生合并,温带气旋所带来的较高纬度冷空气的入侵增强了低层的水平温度梯度,使得低层锋区强烈发展,从Yagi以一个锋面气旋的形式而再度发展,促使其变性后进一步增强。而这些特征都是Francisco所不具备的。 相似文献
8.
热带气旋登陆维持和迅速消亡的诊断研究 总被引:19,自引:6,他引:13
采用动态合成方法, 对登陆后长久维持热带气旋(LTC)和迅速衰亡热带气旋(STC)的涡度、动能、热量和水汽的收支平衡进行计算和对比分析.结果表明: (1)LTC在陆上长久维持过程中, 其低层正涡度衰减缓慢并保持一定强度.STC登陆后正涡度减弱较快.(2)热带气旋登陆后涡度的收支主要取决于水平散度项、平流项和剩余项.散度项使LTC低层正涡度增加, 高层减少, 平流项和剩余项则使其低层涡度减弱, 高层涡度增加.总体而言, LTC自高层获得正涡度的补充, STC则没有获得环境正涡度.(3)低层, 摩擦耗散使LTC动能减少, 但动能通量辐合可补充部分动能而减缓衰减.中高层, LTC登陆后36~60 h动能收大于支, 动能的增加一部分来自于斜压动能制造, 一部分来自于次网格尺度.STC有类似的动能耗散, 却无动能补充.(4)LTC登陆后保持一定强度, 并从外界获得热量和水汽补充来支持积云对流发展, 而积云对流对LTC的维持具有正反馈作用.STC登陆后没有这一过程. 相似文献
9.
利用WRF模式对热带风暴“海马”登陆后减弱,与中纬度系统相互作用后变性加强的过程进行数值模拟。检验结果证明WRF模式能够较好地模拟“海马”变性阶段的路径、强度及降水。利用模拟结果,分析“海马”变性前后的结构特征。台风向北移动的过程中,与西北方向移来的西风槽相遇。台风西北部对应高空急流入口区右侧强辐散区,有强上升运动,同时受锋前抬升作用影响,台风结构发生倾斜,减弱的台风发生变性并加强发展成为锋面气旋。随着变性气旋发展,其北部上升运动加强,向垂直运动区输送水汽的东南暖湿气流加强,从而使台风与中纬度高空槽相互作用区产生强降水。 相似文献
10.
中国大陆上变性加强热带气旋的诊断分析 总被引:1,自引:1,他引:0
利用1979-2007年日本气象厅热带气旋年鉴资料,对在中国大陆上发生变性的热带气旋进行了统计分析,结果表明:29 a间中国大陆上发生变性的热带气旋共有16个,占登陆中国热带气旋总数的8.56%,其中8个变性后加强.利用日本JRA-25再分析资料诊断分析了这8个变性加强热带气旋的湿位涡垂直分布特征以及影响热带气旋变性发... 相似文献
11.
COMPARATIVE ANALYSIS OF THE INTENSIFYING AND WEAKENING LANDFALL TROPICAL CYCLONES DURING EXTRATROPICAL TRANSITION OVER CHINA 总被引:1,自引:1,他引:0
Based on the Tropical Cyclone(TC) Yearbooks data and JRA-25 reanalysis data from the Japan Meteorological Agency(JMA) during 1979-2008, dynamic composite analysis and computation of kinetic energy budget are used to study the intensifying and weakening TCs during Extratropical Transition over China. The TCI shows strong upper-level divergence, strengthened low-level convergence and significantly enhanced upward motion under the influence of strong upper-level troughs and high-level jets. The TCI is correspondingly intensified after Extratropical Transition(ET); TCW exhibits strong upper-level divergence, subdued low-level convergence and slightly enhanced upward motion under the influence of weak upper-level troughs and high-level jets. It then weakens after ET. The increase(decrease) of the generation of kinetic energy by divergence wind in TCI(TCW) at low level is one of the major reasons for TCI’s intensification(TCW’s weakening) after transformation. The generation of kinetic energy by divergence wind is closely related to the development of a low-level baroclinic frontal zone. The growth of the generation of kinetic energy by rotational wind in TCI at upper level is favorable for TCI’s maintenance, which is affected by strong upper-level troughs. The dissipation of the generation of kinetic energy by rotational wind in TCW at upper level is unfavorable for TCW’s maintenance, which is affected by weak upper-level troughs. 相似文献
12.
The extratropical transition (ET) of tropical cyclone (TC) Haima (2004) was simulated to understand the impact of TC on midlatitude frontal systems. Two experiments were conducted using the Advanced Research version of the Weather Research and Forecast (WRF) model. In the control run (CTL), a vortex was extracted from the 24-hour pre-run output and then inserted into the National Centers for Environmental Prediction (NCEP) global final (FNL) analysis as an initial condition, while TC circulation was removed from the initial conditions in the sensitivity run (NOTC). Comparisons of the experiments demonstrate that the midlatitude front has a wider meridional extent in the NOTC run than that in the CTL run. Furthermore, the CTL run produces convection suppression to the southern side of the front due to strong cold advection related to the TC circulation. The easterly flow north of the TC not only decelerates the eastward displacement of the front and contracts its zonal scale but also transports more moisture westward and lifts the air along equivalent potential temperature surfaces ahead of the front. As a result, the ascending motion and diabatic heating are enhanced in the northeastern edge of the front, and the anticyclonic outflow in the upper-level is intensified. The increased pressure gradient and divergent flow aloft strengthen the upper-level jet and distort the trough axis in a northwest-southeast orientation. The thermal contrast between the two systems and the dynamic contribution related to the TC circulation can facilitate scalar and rotational frontogenesis to modulate the frontal structure. 相似文献
13.
A CLIMATOLOGY OF EXTRATROPICAL TRANSITION OF TROPICAL CYCLONES IN THE WESTERN NORTH PACIFIC 总被引:1,自引:1,他引:0
Based on best-track data and JRA-25 reanalysis, a climatology of western North Pacific extratropical
transition (ET) of tropical cyclone (TC) is presented in this paper. It was found that 35% (318 out of 912) of all
TCs underwent ET during 1979–2008. The warm-season (June through September) ETs account for 64% of all ET events
with the most occurrence in September. The area 120°E–150°E and 20°N–40°N is the most favorable region for ET
onsets in western North Pacific. The TCs experience ET at latitudes 30°N–40°N and have the greatest intensity in
contrast to other latitude bands. The distribution of ET onset locations shows obviously meridional migration in
different seasons. A cyclone phase space (CPS) method was used to analyze the TC evolution during ET. Except for
some cases of abnormal ET at relatively high latitudes, typical phase evolution paths—along which TC firstly
showed thermal asymmetry and an upper-level cold core and then lost its low-level warm core—can be used to
describe the main features of ET processes in western North Pacific. Some seasonal variations of ET evolution paths
in CPS were also found at low latitudes south of 15°N, which suggests different ET onset mechanisms there. Further
composite analysis concluded that warm-season ETs have generally two types of evolutions, but only one type in cold
season (October through next May). The first type of warm-season ETs has less baroclinicity due to long distance
between the TC and upper-level mid-latitude system. However, significant interactions between a mid-latitude upper
-level trough and TC, of either approaching or being absorbed into the trough, and TC’s relations with downstream
and upstream upper-level jets, are the fingerprints for both a second type of warm-season ETs and almost all the
cold-season ETs. For each type of ETs, detailed structural characteristics as well as precipitation distribution
are illustrated by latitude. 相似文献
14.
An objective method for discriminating the process of extratropical transition (ET) in tropical cyclones is introduced. With this method, the gridpoint output data of NWP are used to calculate three parameters: storm-relative thickness symmetry (B), low-level (-VLT) and upper-level thermal wind (-VUT). This objective method is easy to calculate and convenient for operational use. To verify the method, this paper uses the NCEP reanalysis data to identify the evolution of ET for "Haima", a tropical storm (0421) that affected the eastern part of China in 2004. The result shows that the three parameters defined with the objective method are good indicators of the ET process. 相似文献
15.
Climatologically, August is the month with the most tropical cyclone(TC) formation over the western North Pacific(WNP) during the typhoon season. In this study, the reason for abnormal TC activity during August is discussed—especially August 2014, when no TCs formed. The large-scale background of August 2014 is presented, with low-level large-scale easterly anomalies and anticyclonic anomalies dominating over the main TC genesis region, a weak monsoon trough system,and a strong WNP subtropical high(WPSH), leading to significantly reduced low-level convergence, upper-level divergence,and mid-level upward motion. These unfavorable large-scale conditions suppressed convection and cyclogenesis. In August2014, equatorial waves were inactive within the negative phase of the Madden–Julian Oscillation(MJO), with fewer tropical disturbances. Although the low-level vorticity and convection of those disturbances were partly promoted by the convective envelopes of equatorial waves, the integral evolution of disturbances, as well as the equatorial waves, were suppressed when propagating into the negative MJO phase. Moreover, the upper-level potential vorticity(PV) streamers associated with anticyclonic Rossby wave breaking events imported extratropical cold and dry air into the tropics. The peripheral tropospheric dryness and enhanced vertical wind shear by PV streamer intrusion combined with the negative MJO phase were responsible for the absence of TC formation over the WNP in August 2014. 相似文献
16.
A real case study for the transformation of Tropical Storm (TS) Haima (2004) into an extratropical cyclone (EC) is carried out numerically since,after landfall,Haima (2004) (as an EC) brought severe weather to a large area (from the south to the north) in China during 13-16 September 2004.With the linear diagnostic model (derived in a previous study) for the tangentially-averaged radial-vertical circulation within vortices moving on the spherical Earth,Haima’s (2004) life cycle is reconstructed noticeably well.Therefore,the major contributor could be identified confidently for Haima’s (2004) extratropical transition based on the diagnostic model outputs.The quantitative comparison shows that up to a 90% contribution to the innerregion updraft and a 55% contribution to the upper-layer outflow come from latent heating during Haima’s (2004) TS stage.Up to a 90% contribution to the inner-region updraft and nearly a 100% contribution to the upper-layer outflow come from the upper-layer eddy angular momentum advection (EAMA) during Haima’s (2004) EC stage.Representing the asymmetric structure of the storm,the predominantly positive contribution of the upper-layer EAMA to Haima’s (2004) transformation is closely associated with the Sshaped westerlies in the upper layer with two jets.One jet in the cyclonic-curvature area carries cyclonic angular momentum into the storm,and the other jet in the anticyclonic-curvature area carries anticyclonic angular momentum out of the storm.Consequently,the newly-increased cyclonic tangential wind is deflected by the Coriolis force to the right to form the upper-layer outflow accompanied by the central-area rising motion,leading to Haima’s (2004) extratropical transition after its landfall. 相似文献
17.
本文基于NCEP再分析资料、TRMM卫星降水资料和RSMC最佳路径集(Best-track Dataset)资料,分析了热带气旋(TC)“天兔”变性过程中降水分布和大尺度环流的演变,并结合片段位涡反演进行修改槽脊的数值试验,研究了环流调整对TC变性过程中非对称降水的影响。结果表明:(1)“天兔”变性前降水集中在路径左侧,伴随着纬向型向经向型调整的背景环流,副热带高压南退的同时减弱西进;(2)TC降水的非对称分布与冷暖锋的相对强弱、水汽输送情况以及高空冷空气下传的落区有直接关系;(3)加强环流调整后,系统斜压性加强,与LOT(降水集中于TC路径左侧)型降水相关的环流指数增大过程随之加强,有利于LOT型降水分布进一步加强。 相似文献
18.
利用非静力中尺度WRF模式输出的0601号"Chanchu"台风模拟资料分析了台风变性过程中的结构演变特征,并从位涡的角度,利用湿位涡方程对"Chanchu"变性过程中强度减弱但却能引发强风暴雨的原因进行了探讨。分析表明:台风在变性过程中,尺度逐渐增大并与东移南下的高空槽不断接近,在与高空槽相互作用之前,台风眼壁及外围雨带雷达回波减弱,最大风速减小,最大风速半径圈向外拓展;高低层位涡相接之后,由于高层正位涡的下传携带冷空气侵入台风,在低层锋区上诱发出气旋性环流,进而重新引发强对流,并在角动量的输送作用下,台风外围环流风速再次增大。变性后高空槽和台风在位相上仍有一定距离,高空槽仅与台风的外围环流相互作用,冷空气没有入侵台风内部,这是"Chanchu"没有重新加强的原因之一。利用锋生函数对引起锋生的各分量进行分析,结果显示非绝热加热是造成锋生的主要原因,散度和变形项的贡献次之,倾斜项对锋生几乎没有贡献。 相似文献
19.
In this paper,by carrying out sensitivity tests of initial conditions and diagnostic analysis of physical fields,the impact factors and the physical mechanism of the unusual track of Morakot in the Taiwan Strait are discussed and examined based on the potential vorticity(PV)inversion.The diagnostic results of NCEP data showed that Morakot’s track was mainly steered by the subtropical high.The breaking of a high-pressure zone was the main cause for the northward turn of Morakot.A sensitivity test of initial conditions showed that the existence of upper-level trough was the leading factor for the breaking of the high-pressure zone.When the intensity was strengthened of the upper-level trough at initial time,the high-pressure zone would break ahead of time,leading to the early northward turn of Morakot.Conversely,when the intensity was weakened,the breaking of the high-pressure zone would be delayed.Especially,when the intensity was weakened to a certain extent,the high-pressure zone would not break.The typhoon,steered by the easterly flow to the south of the high-pressure zone,would keep moving westward,with no turn in the test.The diagnostic analysis of the physical fields based on the sensitivity test revealed that positive vorticity advection and cold advection associated with the upper-level trough weakened the intensity of the high-pressure zone.The upper-level trough affected typhoon’s track indirectly by influencing the high-pressure zone. 相似文献