地形对登陆台风麦莎(2005)影响的数值模拟研究

利用非静力平衡的中尺度模式MM5(V3)对2005年9号台风Matsa("麦莎")登陆后期的过程进行了48h模拟,应用低通滤波器分离模拟结果中的天气尺度和次天气尺度运动,并采用热带气旋动态坐标跟踪考察登陆过程中热带气旋的次天气尺度环流特征.通过研究地形对两种尺度间动能和涡度转换的影响,进一步证明了地形对热带气旋有着不可忽视的影响.结果表明,地形的存在有利于维持热带涡旋性强度,这种影响随气旋中心与地形间距离的缩小而逐渐增强,且强度的增强在对流层中高层表现得更为明显.去掉地形后对流层低层次天气尺度系统向热带气旋输送的动能减少,次天气尺度系统对热带气旋动能的消耗增大;当低层涡度转换项的垂直运动贡献为负时,去掉地形会加剧这种负贡献,即次天气尺度系统从热带气旋得到更多的正涡度;从整体上看,去掉地形后,热带气旋不仅没有从次天气尺度系统获得正涡度,反而将自身的正涡度向外输送.     

季风涡旋对热带气旋生成影响的理想试验研究

利用新一代非静力平衡中尺度数值模式WRF_ARW（3.3.1版本）模拟季风涡旋中热带气旋生成的过程,从动力和热力作用两方面分析大尺度季风涡旋对热带气旋生成的影响。结果表明:从动力学角度来看,能提供较大环境场涡度的季风涡旋不利于扰动涡旋快速发展成热带气旋。初始阶段,由于季风涡旋尺度大,垂直涡度径向梯度弱。而垂直涡度径向梯度的强弱可以通过“涡度隔离”效应影响对流单体向涡旋中心的聚集合并过程。随着扰动的组织化,径向入流对涡度的平流作用越来越重要。对流单体相对最大风速半径的位置对热带气旋生成作用明显,当其集中在最大风速半径附近时涡旋容易快速发展。此外,环境场相对涡度与热带气旋的尺度存在显著正相关。初始尺度大的涡旋最终具有较大的外围尺度,其涡度的分布范围也更广。从热力学角度来说,较大的环境场相对湿度有利于热带气旋的生成。虽然较大的环境场湿度能够诱发较强的外围对流,但同时也会使最大风速半径以内存在丰富的对流,后者能够提供充分的内区非绝热加热,降低中心气压,促进涡旋发展。      

台风榴莲（2001）生成初期中尺度涡旋合并过程研究

由于热带海洋上观测资料的稀缺和热带气旋系统本身发生、发展的复杂性,热带气旋生成机制研究领域至今仍然存在很多未解之谜。已有的观测和模拟研究证明,中尺度涡旋合并过程对于热带气旋的生成可能有触发作用,但尚未见到南海季风槽内热带气旋生成过程中中尺度涡旋合并现象的实例模拟研究。利用新一代中尺度天气研究与预报模式WRF对南海热带气旋榴莲(2001)生成过程中的中尺度涡旋合并过程进行了高分辨率(4 km)数值模拟,并与观测资料进行对比,利用模式输出结果重点分析两个中尺度涡旋合并过程中的主要动力学和热力学特征,并在此基础上进一步分析了合并过程中系统中心附近涡度方程中各项涡度收支的演变情况,最后通过两个敏感性试验与控制试验结果的对比,初步探讨中尺度涡旋合并过程对于热带气旋榴莲生成的作用。结果表明,南海季风槽中的新生中层中尺度涡旋V2,是榴莲生成过程中的主导涡旋,预先存在的东部低层的中尺度涡旋V1对于台风榴莲的生成则起到了辅助作用,两个不同高度的涡旋合并叠加促使涡度的辐合、辐散项率先在低层引起涡度的快速增长,随后垂直输送项在对流层中层对涡度的增长起主要作用。两个涡旋的最终合并,使热带气旋系统正绝对涡度在垂直方向上从低层到中层得以贯通,进而触发榴莲的生成。     

热带气旋Haiyan(2013)快速增强过程内核涡度变化机制的数值模拟研究

选取西北太平洋热带气旋Haiyan(2013)为研究对象,利用中尺度数值模式WRF对其快速增强(RI)过程进行了高时空分辨率的数值模拟,推导出一个包含不同尺度系统相互作用的垂直涡度诊断方程来探究TC内核区域相对涡度的变化特征及其与RI的联系。诊断结果表明:涡旋尺度散度项(stre2)、倾斜项(tilt2)和垂直平流项(advv2)对涡度收支的影响最为重要。RI开始前,stre2在边界层内对涡度收支为正贡献,边界层之上则为负贡献;tilt2在低层促进涡度增加;advv2分布与stre2相反,在低层为负值,高层为正值。RI开始后,stre2在低层(高层)对涡度的正(负)贡献显著增强;tilt2在低层(高层)对涡度的促进(抑制)作用明显增强,但在中层出现正负贡献相互交替的情况;advv2在低层对涡度的正贡献也有所增强。     

热带气旋外眼墙形成机制研究综述

介绍了国内外关于热带气旋外眼墙形成和维持过程的相关研究进展,包括大尺度环境场和热带气旋涡旋内部动力学过程,如涡旋罗斯贝波理论、轴对称化过程、涡丝化作用、β-skirt轴对称化外眼墙形成假说和边界层非平衡动力过程等。随着对外眼墙形成机理研究的不断深入,当前存在多种外眼墙形成的机制理论,而这些机制均强调在外眼墙的形成阶段,热带气旋外围有大量对流及位势涡度扰动的发生发展。因此,热带气旋外眼墙的形成很有可能是多种机制相互作用导致的。最后,提出研究多种机制相互作用导致外眼墙处的对流和位势涡度扰动的发生发展过程具有重大意义。     

非对称环流的细致结构与台风路径的摆动

应用准地转三层斜压模式数值模拟热带气旋的移动，详细分析热带气旋非对称环流的三度空间结构及其与热带气旋移动的关系。结果表明：非线性涡度平流与线性β项相结合不但可以产生大尺度β涡旋对，而且还可产生小尺度涡旋对；这两种不同尺度的非对称涡旋不断相互作用，导致热带旋移速的振荡和移向的摆动。     

涡旋自组织过程影响0604号热带气旋Bilis降水的数值研究

利用PSU/NCAR中尺度天气预报模式MM5,成功模拟了0604号热带气旋Bilis登陆后的移动路径和降水分布。在此基础上,讨论了不同尺度涡旋自组织过程对热带气旋Bilis产生局地暴雨的影响。结果表明:(1)引发强降水的对流系统不是来源于热带气旋螺旋云带内的对流云团,而是受热带气旋外围环流与局地地形影响下形成的多个中小尺度系统之间自组织的结果;(2)与0604号热带气旋Bilis登陆前后24小时的强降水相关的自组织过程是分阶段进行的,即第一阶段的双涡自组织过程和第二阶段的多涡自组织过程;(3)局地多尺度涡旋之间的自组织过程,是0604号热带气旋Bilis陆上强降水发生的主要动力机制。     

西北太平洋热带气旋快速增强阶段的风速分布特征

利用联合台风预警中心的最优路径（best-track）资料,筛选出西北太平洋地区快速增强和非快速增强两类热带气旋样本。利用美国国家海洋与大气管理局（NOAA）的多平台热带气旋表面风分析资料,对比分析了两类样本的风速和涡度的分布特征。结果显示,快速增强的热带气旋样本通常结构更紧凑,最大风速较大,最大风速半径较小,台风内区的风速较大。在涡度上表现为快速增强热带气旋样本内区的涡度和涡度梯度较大。对两类样本进行t检验,结果显示两类样本内区的切向风差异明显,说明热带气旋的内区风速分布与其发展之间存在密切联系。其物理机制可能是:当存在较大的内区涡度梯度时,涡度隔离机制有利于对流单体向涡旋中心汇聚,此外较大的涡度意味着较大的惯性稳定度,有利于非绝热加热向热带气旋动能的转换,二者共同作用有利于热带气旋的快速发展。      

一次双台风影响下暴雨过程的中尺度涡旋模拟分析

本文对上海地区一次双台风环境影响的暴雨过程进行数值模拟及分析,探讨了强降水过程中大气中低层的涡旋特征及发展机理。结果表明:(1)暴雨过程处于双台风、大陆高压的共同影响下,中低层伴随有较明显的中尺度低涡发展。(2)与涡旋相关的局地垂直涡度由低层开始发展,先期涡度发展集中于850 hPa以下,之后向大气中上层发展增强,涡旋尺度强度也随之发展,最终形成在对流层下半部具有闭合式气旋性环流的深厚涡旋。(3)影响局地涡度变化的水平平流项、垂直平流项、散度制造项和倾斜项对不同时间、不同高度的涡度作用各不相同,其中散度制造项是中低层涡度的主要来源,垂直平流项的输送作用对中上层的涡度发展有重要作用,倾斜项对涡旋发展移动也有部分贡献。(4)通过敏感性试验考察了对流潜热反馈的贡献,发现潜热释放过程通过加热改变大气温压场结构,从而维持并改变局地涡度倾向的中低层辐合及对流上升运动,对涡旋的发展和移动起了重要影响。     

热带气旋生成过程的中尺度涡旋活动数值模拟

热带气旋生成过程中包含不同尺度环流及其相互作用。为此,本文将热带气旋生成数值模拟的起点提前到模拟中尺度涡旋(MCV)的生成,从而利用高分辨率数值试验结果,对热带气旋过程中的不同尺度涡旋活动进行分析。模式首先模拟了季风涡旋的东南侧增强的西南气流中出现低形变旋转性扰动,随着扰动的旋转性增强,中层出现水平尺度为200 km左右的MCV。在扰动区内的不同高度上还发现10~20 km尺度不等的中γ气旋性涡旋扰动,其中部分涡旋扰动具有热塔的特征,中γ气旋性涡旋扰动在MCV的旋转环境内不断组织化,低层气旋性涡旋扰动的分布比中层更加集中。模拟表明这些较小尺度的气旋性中尺度涡旋扰动对热带气旋的生成有重要作用。     

Interaction of typhoon and mesoscale vortex

Under two types of initial tropical cyclone structures that are characterized by high and low vorticity zones, four sets of numerical experiments have been performed to investigate the interaction of a tropical cyclone with an adjacent mesoscale vortex (MSV) and its impact on the tropical cyclone intensity change,using a quasi-geostrophic barotropic vorticity equation model with a horizontal resolution of 0.5 km. The results suggest that the interaction of a tropical cyclone characterized by a high vorticity zonal structure and an MSV would result in an intensification of the cyclone. Its central pressure decreases by more than 14 hPa. In the process of tile interaction, the west and middle segments of the high vorticity zone evolve into two peripheral spiral bands of the tropical cyclone, and the merging of the east segment and the inward propagating MSV forms a new vorticity accumulation area, wherein the maximum vorticity is remarkably greater than that in the center of the initial tropical cyclone circulation. It is this process of merging and strengthening that causes a greater pressure decrease in the center of the tropical cyclone. This process is also more complicated than those that have been studied in the past, which indicated that only the inward transfer of vorticity of the MSV can result in the strengthening of the tropical cyclone.     

EFFECT OF THE NONLINEAR TERM ON MOVEMENT AND DEVELOPMENT OF TROPICAL CYCLONE

The dynamics of tropical cyclone is investigated in a nondivergent barotropic model with nobasic flow. The effect of nonlinear term on the movement and development of tropical cyclone isemphatically demonstrated. The advection of asymmetric vorticity by the symmetric flow (AAVS)produces the small-scale gyres (SSGs). The SSGs counterclockwise rotate around the tropicalcyclone center. The interaction of SSGs with the large-scale beta gyres (LSBGs) leads to theoscillation in translation speed and vacillation in translation direction for tropical cyclone. Theadvection of symmetric vorticity by the asymmetric flow (ASVA) steers the symmetric circulationof tropical cyclone. The ventilation flow vector determined by the asymmetric flow is closecorrelated with the motion vector of tropical cyclone. The nonlinear advection of relative vorticityis an order of magnitude greater than the linear advection of planetary vorticity, However, theasymmetric circulation created by the planetary vorticity advection provides a background conditionfor anomalous motions of the tropical cyclone. The combination of the linear and nonlinear effectsresults in accelerated, decelerated, changing direction and/or counterclockwise looping motions ofthe tropical cyclone.     

EFFECT OF THE NONLINEAR TERM ON MOVEMENT AND DEVELOPMENT OF TROPICAL CYCLONE*

The dynamics of tropical cyclone is investigated in a nondivergent barotropic model with no basic flow. The effect of nonlinear term on the movement and development of tropical cyclone is emphatically demonstrated. The advection of asymmetric vorticity by the symmetric flow(AAVS) produces the small-scale gyres(SSGs). The SSGs counterclockwise rotate around the tropical cyclone center. The interaction of SSGs with the large-scale beta gyres(LSBGs) leads to the oscillation in translation speed and vacillation in translation direction for tropical cyclone. The advection of symmetric vorticity by the asymmetric flow(ASVA) steers the symmetric circulation of tropical cyclone. The ventilation flow vector determined by the asymmetric flow is close correlated with the motion vector of tropical cyclone. The nonlinear advection of relative vorticity is an order of magnitude greater than the linear advection of planetary vorticity, However, the asymmetric circulation created by the planetary vorticity advection provides a background condition for anomalous motions of the tropical cyclone. The combination of the linear and nonlinear effects results in accelerated, decelerated, changing direction and/or counterclockwise looping motions of the tropical cyclone.     

Simulation of formation of a near-equatorial typhoon Vamei (2001)

Summary A community mesoscale model is used to simulate and understand processes that led to the formation and intensification of the near-equatorial typhoon Vamei that formed in the South China Sea in December, 2001. The simulated typhoon resembles the observed in that it had a short lifetime and a small size, formed near the equator (south of 2° N), and reached category-one intensity. The formation involved the interactions between the scales of the background cyclonic circulation (the Borneo Vortex of order ∼100 km) and of mesoscale convective vortices (MCVs, in the order ∼10 km). Before tropical cyclone formation MCVs formed along a convergent, horizontal shear vorticity line on the eastern edge of an exceptionally strong monsoonal northerly wind surge. The typhoon genesis is marked by three rapid intensification periods, which are associated with the rapid growth of potential vorticity (PV). A vorticity budget analysis reveals that the increases in low-level vorticity during the rapid intensification periods are attributed to enhanced horizontal vorticity fluxes into the storm core. The increase of the horizontal vorticity flux is associated with the merging of areas of high PV associated with MCVs into the storm core as they are advected by background cyclonic flows. The increases in PV at upper levels are associated with the evaporation of upper level stratiform precipitation and increases of vertical potential temperature gradient below the maximum stratiform cloud layer. It appears that two key sources of PV at upper and lower levels are crucial for the build up of high PV and a deepening of a cyclonic layer throughout the troposphere.     

湿斜压性与热带气旋强度突变

应用湿位涡方程和倾斜涡度发展理论 ,研究了热带气旋内部相当位温结构的演变与其强度突变的可能关系 ,并用一套高分辨率的模拟资料对所得结论进行验证。结果表明 ,由于热带气旋眼壁附近等相当位温面陡立 ,湿斜压性变化所激发的倾斜涡度发展是引起该区域垂直涡度突然增大或突然减小的主要原因。当热带气旋中心附近大部分区域的垂直涡度显著增长时 ,热带气旋就会在整体上表现为爆发性或迅速发展。最后还据此对同心双眼结构的出现和消失如何影响热带气旋强度变化进行了探讨。     

EFFECTS OF VERTICAL WIND SHEAR ON INTENSITY AND STRUCTURE OF TROPICAL CYCLONE

In this study,the effect of vertical wind shear(VWS)on the intensification of tropical cyclone(TC)is investigated via the numerical simulations.Results indicate that weak shear tends to facilitate the development of TC while strong shear appears to inhibit the intensification of TC.As the VWS is imposed on the TC,the vortex of the cyclone tends to tilt vertically and significantly in the upper troposphere.Consequently,the upward motion is considerably enhanced in the downshear side of the storm center and correspondingly,the low-to mid-level potential temperature decreases under the effect of adiabatic cooling,which leads to the increase of the low-to mid-level static instability and relative humidity and then facilitates the burst of convection.In the case of weak shear,the vertical tilting of the vortex is weak and the increase of ascent,static instability and relative humidity occur in the area close to the TC center.Therefore,active convection happens in the TC center region and facilitates the enhancement of vorticity in the inner core region and then the intensification of TC.In contrast,due to strong VWS,the increase of the ascent,static instability and relative humidity induced by the vertical tilting mainly appear in the outer region of TC in the case with stronger shear,and the convection in the inner-core area of TC is rather weak and convective activity mainly happens in the outer-region of the TC.Therefore,the development of a warm core is inhibited and then the intensification of TC is delayed.Different from previous numerical results obtained by imposing VWS suddenly to a strong TC,the simulation performed in this work shows that,even when the VWS is as strong as 12 m s-1,the tropical storm can still experience rapid intensification and finally develop into a strong tropical cyclone after a relatively long period of adjustment.It is found that the convection plays an important role in the adjusting period.On one hand,the convection leads to the horizontal convergence of the low-level vorticity flux and therefore leads to the enhancement of the low-level vorticity in the inner-core area of the cyclone.On the other hand,the active ascent accompanying the convection tends to transport the low-level vorticity to the middle levels.The enhanced vorticity in the lower to middle troposphere strengths the interaction between the low-and mid-level cyclonical circulation and the upper-level circulation deviated from the storm center under the effect of VWS.As a result,the vertical tilting of the vortex is considerably decreased,and then the cyclone starts to develop rapidly.     

Parameterization of a momentum source in a tropical cumulus ensemble

Summary An eddy effect of tropical deep convection on the large-scale momentum, resp vorticity budget is investigated. The process is specified by a simple parameterization approach which is based on a concept of rotating clouds exerting a momentum on the large-scale flow. The cloud rotation is associated with the thermal properties of a cloud ensemble by the principle of conservation of potential vorticity. A decomposition of cloud classes is applied in consistency with the thermodynamical parameterization scheme of Arakawa and Schubert (1974).The parameterization is tested with observations of GATE74, Phase III. The data are processed on a B/C-scale grid (55km) in a region within 9N and 16N, and between 21W and 27W, and with a vertical resolution of 41 levels. The parameterization results correspond to the observed patterns, especially in situations with strong large-scale wind shear. The findings suggest that certain large-scalle flow regimes provoke convective scale momentum generation rather than redistributing large-scale momentum by convective circulations.With 10 Figures     

不同尺度涡旋相互作用对台风的结构和移动的影响

根据大气运动原始方程组导出一个支配台风中心移动的基本方程，方程中包括了非绝热加热，温度场分布，地形与摩擦等各中能影响台风移动的强迫因子。对非绝热加热与水平温度分布的使用所作分析表明，非轴对称的非绝热引导作用可使台风加速、减速或转向运动；温度场上的准区对台风有吸收作用。