共查询到20条相似文献,搜索用时 390 毫秒
1.
A uniform,inviscid,incompressible fluid in a two-dimensional plane(x,z)is considered.Three principles:conservation of potential vorticity,conservation of absolute momentum,and conservation of mass are used for this study.If the initial mass field and the initial wind field do not satisfy geostrophic balance,then through geostrophic adjustment under suitable conditions,the frontogenesis will finally occur.Our work points out that the initial density distribution greatly influences the frontal features.If the stratification in cold air is the same as that in warm air,two frontogeneses will occur at top and bottom boundaries respectively.If the stratification in cold air is larger than that in warm air,the frontogenesis at the bottom boundary still exists,but the other at the top boundary disappears.This result makes us further understand the mechanism of the frontogenesis in the real atmosphere. 相似文献
2.
Geostrophic adjustment and frontogenesis are examined by means of the 2-D ARPS model.The simulation shows that.without the large-scale forcing,both the frontogenesis and frontolysisare observed during the geostrophic adjustment process and the intensity of the front oscillates inthe case of no discontinuity.The convergence (divergence) induced by the secondary circulation isthe most important factor for frontogenesis (frontolysis) at the top and bottom boundaries.Theamplitude and period of oscillation are dependent on the initial atmospheric stratification and theCoriolis frequency,and they are related to the inertio-gravity wave. 相似文献
3.
Geostrophic adjustment and frontogenesis are examined by means of the 2-D ARPS model.The simulation shows that.without the large-scale forcing,both the frontogenesis and frontolysisare observed during the geostrophic adjustment process and the intensity of the front oscillates inthe case of no discontinuity.The convergence (divergence) induced by the secondary circulation isthe most important factor for frontogenesis (frontolysis) at the top and bottom boundaries.Theamplitude and period of oscillation are dependent on the initial atmospheric stratification and theCoriolis frequency,and they are related to the inertio-gravity wave. 相似文献
4.
作者的目的是分析地形对由于热力差异所引起的局地锋生现象和地转适应过程的影响.为此,分别用零位涡流和均匀位涡流来近似代替实际大气,并借助位涡、绝对动量、位温的守恒关系,就地形对适应锋生和适应过程中能量转换等问题进行了简单讨论。初始位温扰动的水平分布及其相对于地形的位置对适应锋生有重要影响。当初始热力扰动主要位于地形迎风坡山脚时,地形不利于锋面形成,这时要形成锋面不连续,初始位温梯度的水平变化必须非常显著;当初始热力扰动主要位于山顶附近时,地形促进流体运动的辐合,有利于锋面不连续的形成,这时即使初始位温梯度的水平变化不是很大,也可能会形成锋面;当初始热力扰动主要位于背风坡时,地形是否有利于锋面不连续的形成取决于流体的层结情况,如果流体的基本层结很弱,地形促进锋面不连续的形成,反之,地形不利于锋面不连续的形成,这种差异主要是由于在这两种情况下,地形引起的下沉增温效应的强弱是不同的。另外,地形对地转适应过程中动能和位能之间的能量转换率也有影响,与没有地形的情况相比,当初始热力差异显著区位于迎风坡时,能量转换率减小,当不平衡场位于背风坡时,能量转换率增加,原因是在迎风坡流体要克服重力作功,在背风坡重力对流体作正功。 相似文献
5.
6.
Evolution and Frontogenesis of an Imbalanced Flow —the Influence of Vapor Distribution and Orographic Forcing 总被引:1,自引:0,他引:1
1.InttoductionIftheinitialfieldsarenotingeostrophicbalance,theadjustmentandevolutionwilloccurinthestratifiedfluid,andthefrontogenesiswilloccurundersuitableconditions.ThisaspectwasfirstinvestigatedbyRossby(1938),followedbymanyscientists(Blumen,1972;Gill,1976,1982;VanHeijst,1985;BossandThompson,1985;On,1984,1986;McWilliams,1988;Middleton,1987;Glendening,1993;BlumenandWu,1995;WuandBlumen,1995;Grimshaw1998;Blumen,1998;etc.).Intheseresearches,theenergyconversionratioy=AEk/BE,isaninterestin… 相似文献
7.
If the initial fields are not in geostrophic balance, the adjustment and evolution will occur in the stratified fluid, and the frontogenesis will occur under suitable conditions. The evolution is studied here with a nonhydrostatic fully compressible meso-scale model (Advanced Regional Prediction System, ARPS). Four cases are designed and compared: (i) control experiment; (ii) with different initial temperature gradient; (iii) with vapor distribution; (iv) with orographic forcing. The results show that: (1) there is an inertial oscillation in the evolution of the imbalanced flow with the frequency of the local Coriolis f, and with its amplitude de-creasing with time. The stationary balanced state can only be approached as it cannot be reached in the limit duration of time, The energy conversion ratio varies in the range of [0, 1 / 3]; (2) the stronger initial tempera-ture gradient can make the final energy conversion ratio higher, and vice versa; (3) suitable vapor distribu-tion is favorable for the frontogenesis. It will bring forward the time of the frontogenesis, strengthen the in-tensity of the cold front, and influence the final energy conversion ratio; (4) the orographic forcing has an ev-idently strengthening effect on the frontogenesis. The strengthening effect on the frontogenesis and the influ-ence on the final energy conversion ratio depend on the relative location of the mountain to the cold front. 相似文献
8.
黄淮气旋引发山东两次暴雨过程的对比分析 总被引:1,自引:0,他引:1
利用常规天气图资料和NCEP再分析资料,对2002年5月14日和2013年5月26日发生在山东的两次气旋暴雨过程进行对比分析。结果表明:两次过程均是在高空低槽、西南涡及地面气旋共同作用下形成的,但气旋形成方式、高低空急流及空气不稳定层结有明显的差异。前者为倒槽锋生型,空气层结呈对流性稳定,冷暖空气在近地层交汇使得等熵面陡立触发垂直涡度增长和湿对称不稳定能量释放造成暴雨,后者为静止锋上冷暖平流加强形成气旋波,冷空气团叠加在暖湿气流之上通过降低低层稳定度强迫暖空气抬升触发对流不稳定能量释放造成暴雨;前者高空急流偏南,后者高低空急流配合较好激发出次级环流从而使上升运动增强;两次过程暴雨落区均在850hPa高能轴顶端冷暖空气交汇处。 相似文献
9.
利用中国气象局热带气旋年鉴、FY-2D(0.1°×0.1°)云顶亮温、逐时自动气象站降雨量、常规观测资料和NCEP/NCAR再分析资料,运用锋生函数对台风“麦德姆”(Matmo,1410)影响辽东半岛和山东半岛期间的降水特征进行了诊断分析。结果表明:1)Matmo影响辽东半岛和山东半岛期间,其低压环流与西风带高空槽相互作用,在其西侧和东北侧分别有冷锋和暖锋锋生,两条锋带均向东移。强锋生区首先在低层生成,随后尽管高空锋区向下延伸,但并未与低层冷锋重合,低层冷锋锋生强度减弱。2)山东半岛和辽东半岛的降水均发生在台风低压环流的锋生过程中,但山东半岛的降水明显多于辽东半岛。这与锋生强度密切相关,辽东半岛的锋生强度和垂直运动较山东半岛明显偏弱。3)强降水与台风环流内冷、暖平流活动密切相关,冷暖平流交汇之处对强降水有较好的示踪作用。山东半岛始终处于冷暖平流交汇处,其西侧斜压不稳定加强,上升运动发展,强降水出现在冷锋带上暖平流区内;而辽东半岛由冷平流转为暖平流时,对流运动向其东北方向发展,强降水位于辽东半岛东北部。 相似文献
10.
11.
During the Intensive Observation Period (IOP) 7 (22 February 1986) of the Genesis of Atlantic Lows Experiment a persistent coastal front was observed along the Carolina coast in the eastern United States. An intensive baroclinic zone, associated with the cold air damming to the east of the Appalachian Mountains, and the warm marine atmospheric boundary layer over the Gulf Stream, resulted in a northeasterly low-level geostrophic wind maximum near the coast.Two convergence zones were observed, one near the shore and the other near the western edge of the Gulf Stream. The convergence zone near the coastline was relatively weaker than that near the Gulf Stream. The differential surface thermal forcing caused enhanced convergence associated with the frontogenesis, and a meso-low was observed over the offshore front. The terms in the frontogenesis equation are estimated, and the diabatic term is found to be larger than the frontogenetic confluence term along the shore. 相似文献
12.
该文通过对1996年6月13日山东大范围冷涡降雹过程与同年6月20日不降雹冷涡的对比分析指出:降雹与不降雹冷涡,除了冷涡北侧的高空形势有明显差异外,主要表现在低层的风场、温度场和层结稳定度有显著区别。当高空冷涡进入华北上空时,若北侧有高压脊向东北方向伸展,沿脊前有东北气流侵入冷涡后部。同时,低层在40°N附近有明显的东西向锋区配合锋生变形场逼近鲁西北一带的潜在不稳定区,该冷涡会造成山东大范围降雹。而当高空冷涡发展为较对称的深厚气旋时,处于冷涡南侧的山东地区则不会出现强对流天气。 相似文献
13.
ANALYSIS OF THE COLD AIR EFFECT ON AN EXTREME PRECIPITATION EVENT TRIGGERED BY AN INVERTED TROUGH OF TYPHOON HAIKUI (1211) 总被引:1,自引:0,他引:1
Based on intensive automatic weather station data, satellite cloud imagery, NCEP reanalyzed data, and the simulation results from mesoscale numerical models, this study analyzes the characteristics and formation mechanisms of the mesoscale convection system (MCS) during the extreme precipitation event that was triggered by a weakened low-pressure inverted trough of Typhoon Haikui on August 10/2012. The results of this study show that cold air at the rear of a northeastern cold vortex creates thermodynamic conditions favorable to the development of extreme precipitation. The main body of the cold air is northward located so that the cold air invades only the middle layer of the periphery of the inverted trough. Thus, the cold air minimally affects the lower layer, which results in a vertically distributed structure of the temperature advection that augments the formation and development of convective instability stratification. In the middle troposphere, the cold air encounters the convergent, ascending, warm moist air from the low-pressure inverted trough, leading to frontogenesis. The frontogenesis enhances wind convergence which, in turn, further enhances the frontogenesis, and the positive feedback between these two forces augments the development of meso- and small-scale convection systems in the rainstorm region and its vicinity, which strengthens the upward transportation of water vapor from low layers and thickening of water vapor convergence and results in local heavy rains. 相似文献
14.
一次冬季锋面暴风雪天气过程的斜压边界层特征的观测分析 总被引:4,自引:0,他引:4
对STORM-FESTIOP17一次冬季锋面暴风雪天气过程的斜压边界层结构演变及特征进行了分析。发现:暖湿空气沿锋面抬升凝结成云,产生降水过程中释放的大量潜热显著增加锋两侧的水平温度差异,产生锋生。与锋生相伴,在锋前产生低空急流和高空急流。当锋生至最强时,锋两侧温差可达20K,锋前低空急流开始减弱,锋后低空急流增强,锋后冷平流开始主导锋两侧的环流系统。该冷平流削弱锋两侧的温度水平梯度,产生锋消作用。对这次锋面斜压对流边界层的湍流特征分析表明:在边界层之上切应力wv明显增大;湍能收支分析表明在边界层之上的风切变产生项很强,即大尺度天气系统有利于斜压对流边界层的发展,边界层内各量充分混合。这次冬季锋面暴风雪天气过程,冷锋前的低空南风急流从墨西哥湾携带来的充足水汽及锋区边界层大气的强斜压性是其产生的关键因子:冷锋过后,大尺度高空急流的作用更有利于对流边界层的充分发展。 相似文献
15.
利用气旋相空间法(cyclone phase space,CPS)对1403号台风Faxai变性前后的环境场及结构演变特征进行分析。结果表明:相空间法能够很好地指示低纬变性台风Faxai的变性起止时间。此次过程是由减弱的台风环流与TC西北侧的短波槽结合发展产生,分析台风Faxai的结构演变特征可知,变性阶段TC低层厚度场由均匀对称分布转为非均匀分布,增大了环境斜压性,变性后B值最大达30 m,为弱的斜压非对称结构。Faxai东侧的偏南风暖湿气流与偏北风气流相交汇,使得经向位温梯度增加从而在TC东北象限形成一带状锋区,锋区正好位于南北两大风圈之间的位置。整个变性阶段Faxai西侧几乎无明显冷锋锋生,只在环流东北侧有一定程度的暖锋锋生,这与典型的锋面气旋的发展过程有所不同。变性前,TC呈现对称分布的暖核结构;变性阶段,冷空气从热带低压西侧对流层中低层下沉入侵,TC呈现左侧冷、右侧暖的非对称斜压结构,中层增温可能与槽后强的下沉气流有关。对锋生函数各分量分析发现,散度场主导了气旋周围的标量锋生,倾斜项的贡献次之,涡度场是引起旋转锋生的主要因素,其余两项可忽略不计。 相似文献
16.
该文提出了冷锋的不连续传播是引起冷锋快速南移的直接原因的观点,即主冷锋南侧的锋生及其发展代替了主冷锋,在南方的锋生过程中,西南低空急流起了重要作用。 相似文献
17.
变形场锋生对0108登陆台风温带变性和暴雨形成作用的诊断分析 总被引:12,自引:2,他引:10
文中利用MM5模式对0108(桃芝)台风温带变性特征及暴雨的发生发展机制进行了诊断分析。分析表明0108(桃芝)台风登陆后其大风区向外扩展,中心区以外的气压仍有下降。由于锋面的斜压作用其温度场结构发生了明显变化,由对称的暖心结构演变为半暖半冷的温带气旋非对称结构,相对应的高度场、流场特征亦表现出非对称结构。通过计算变形向量、锋生函数及非地转风的分布,发现在锋生函数中变形项所起作用比散度项和倾斜项要早、要大,对台风温带变性有重要的作用。而锋生结果加强了风场的非地转性并强迫出锋面垂直次级环流,造成强烈的辐合上升运动,引起台风暴雨的增幅。 相似文献
18.
Using National Centers for Environmental Prediction reanalysis data for the period 28 June to 12 July during 2001 to2013, the secondary circulation(SC) associated with the mei-yu front was quantitatively diagnosed by numerically solving a primitive version of the Sawyer-Eliassen equation. Results demonstrate that a direct SC exists near the mei-yu front zone during mid-summer and the synoptic-scale geostrophic deformations are the main factors determining SC structures. About94% of the sinking strength and 61% of the ascending strength in the SC are induced by the geostrophic deformations.Other terms, such as diabatic heating, ageostrophic dynamical forcing, and frictional forcing, mainly influence the fine flow pattern of the SC. The forced SC produces a frontogenesis area tilting to the north with altitude. Further diagnosis clarifies the positive feedback involving the geostrophic shear forcing and vorticity frontogenesis in the upper-level mei-yu front zone. Furthermore, statistical results indicate that all 34 deep convection cases that occurred in the warm region of the meiyu front over the period 2004-2013 experienced high-level frontogenesis associated with along-jet cold advection. The cyclonic shear forcing "moved" the monsoon SC's subsidence branch to the warm side of the mei-yu front and caused the subsidence branch to extend downwards to the lower troposphere, conducive to the initiation of deep convection in the warm region of the mei-yu front. 相似文献
19.
A warm on-ice air flow from the open water over the Arctic sea ice in the Fram Straitwas, for the first time, systematically measured on 12 March 1998 by aircraft in thelowest 3 km over a 300-km long distance. The air mass modification and the processesinvolved are discussed.Over the water, air temperature was lower than water temperature so that a convectiveboundary layer (CBL) was present as initial condition. As soon as the CBL passed theice edge, a shallow stable internal boundary layer (IBL) was formed. In the residual CBL, turbulence and pre-existing convective clouds dissolved within about 20 km. Within about the same distance, due to the transition from unstable to stable stratification, the influence of surface friction increased in the IBL and decreased above the IBL with consequent generation of a low-level jet at IBL top. The IBL was strongly stratified with respect to both temperature and wind. The wind shear was around 0.1 s-1 so that the Richardson number in the IBL was subcritical and turbulence was generated. The IBL top grew to about 145 m over 230 km distance. The growth of the IBL was not monotonic and was influenced by (a) inhomogeneous ice surface temperatures causedby both different ice thickness and changes in the cloud conditions, and (b) leads in theice deck. At the front side of the on-ice flow, the air mass boundary between the warmair and the cold Arctic air was sharp (12 K over 10 km) at low levels and tilted withheight. Observations suggest that the stratified IBL was lifted as a slab on top of thecold air. 相似文献
20.
利用一个有地形、边界层摩擦作用、简化的二层浅水锋面模型,在理论上研究了地形上空边界层流动中地面暖锋的结构及环流分布特征问题。暖锋的坡度主要取决于其暖域地转流、锋面移速,它随锋面移速增大而减小,这与冷锋特征相反。地形对暖锋坡度的影响作用较小。与无地形作用时相比,静止性暖锋冷域中,位于锋面界面附近的闭合正环流系,当暖锋位于地形上游,其伸展范围增大;当暖锋位于迎风坡时,其伸展范围缩小,中心位置上抬;锋面移至背风坡时,其伸展范围重新增大。对于冷域中远离地面暖锋的另一支正环流系来说,当暖锋位于地形上游或迎风坡时,它可被地形完全阻塞于背风侧,地形高度越高,地形阻塞作用越大。在暖锋锋区附近主要存在三支垂直上升运动带:(a)由于边界层摩擦辐合作用,导致在地面暖锋后缘暖区中形成一支水平尺度较小、强度较大的垂直运动带,它随着暖锋移速增大而减弱。该垂直运动带,当暖锋位于地形迎风侧,强度增加;暖锋位于地形背风侧,其强度减弱。(b)在锋区暖域沿锋面存在均匀的上升运动,(c)在冷域远离地面暖锋处,存在一支水平范围较宽,其中心位于边界层顶部附近的垂直运动带,当暖锋位于迎风坡时,这支垂直运动带可被地形阻塞于地形背风侧。 相似文献