Effect of condensation latent heat release on the relative vorticity tendency in extratropical cyclones:a case study

Taking an extratropical cyclone that produced extreme precipitation as the research object,this paper calculates the contribution of condensation latent heat release(LHR)to relative vorticity tendency based on the complete-form vertical vorticity tendency equation.The results show that the heating rate of convectional condensation LHR can reach up to about 40 times that of stable condensation LHR.Both the stable and convectional heating centers are higher than 700 hPa,which would cause∂Q/∂z>0 and a positive vorticity source in the lower troposphere.The vertical gradient of stable condensation LHR contributes little to the growth of relative vorticity,while the relative vorticity tendency associated with the vertical gradient of convectional condensation LHR can be an order of magnitude higher than the former.The positive vorticity source is always located right below the latent heating center,and its maximum value can always be found in the lower troposphere.Convectional LHR is the primary factor for cyclone development from the perspective of diabatic heating.The horizontal gradient of total condensation LHR can contribute about 65%of the actual vorticity growth,but the effect of the vertical gradient of convectional condensation(LHR)can reach twice as much.The adiabatic heating from LHR can cause vorticity tendency directly.However,it can also change the vertical and horizontal gradient of potential temperature,which can further induce vorticity tendency.

Discussion on the Complete-Form Vorticity Equation and Slantwise Vorticity Development

The complete form of the vertical vorticity tendency equation （the complete-form vorticity equation） is derived from the Ertel potential vorticity equation to contain thermodynamic factors. In this study, a new complete-form vorticity equation, which has the same form as the original complete-form vorticity equation, is deduced from the absolute vorticity vector equation combined with the continuity equation and the expression of three-dimensional （3D） entropy gradient. By comparing the complete-form vorticity equation with the classical vertical vorticity equation, it is found that regardless of whether or not the isentropic surface is tilting, the two vorticity equations are in essence the same. The ＂baroclinic term＂ of the complete-form vorticity equation is exactly equal to the solenoidal term of the classical one, and there is a significant amount of cancellation between the two baroclinic items （the ＂slantwise term＂ and the horizontal vorticity change term） in the complete-form vorticity equation. In operational weather analysis, the tilt of the isentropic surface can be diagnosed according to the density of the isotherm on the upper-level isobaric map. For synoptic-scale motion, the vertical vorticity produced by the tilt of the isentropic surface is due to the contribution of atmospheric baroclinicity, which is measured by the solenoid. The 3D solenoid is parallel to the isentropic surface, so the more tilted the isentropic surface, the bigger the projection of the 3D solenoid in the vertical direction. The baroclinic contribution can be interpreted based on the PV thinking theory, but the relationship between the vorticity field and the potential vorticity field is not immediate.

2003年7月西太平洋副热带高压变异及中国南方高温形成机理研究

运用全型垂直涡度倾向方程理论,研究了空间非绝热加热在垂直方向的变化对2003年7月副高强度和位置变异的影响。结果表明:副热带地区的非绝热加热对副高的强度和位置的变化有极其重要的影响。与气候平均状况相比较,2003年7月副高北侧、西侧非绝热加热的垂直变化异常偏强,而南侧、东侧较常年异常偏弱。这种异常的非绝热加热状况导致我国江南到副热带西太平洋地区呈现带状的异常反气旋性涡度制造,使得7月副高偏强偏西。

空间非均匀加热对副热带高压带形成和变异的影响Ⅰ:尺度分析

利用全型垂直涡度倾向方程，讨论了空间非均匀非绝热加热（Ｑ）对副热带高压形态变异的影响。通过简单的空间尺度分析指出，Ｑ的垂直非均匀分布比其水平非均匀分布对副热带高压带断裂成闭合中心的影响更大。在时间尺度较长时，低空的β效应和高层的涡度平流对副热带高压形态的形成有重要作用。在它们影响下，低空副热带高压出现在表面感热加热西侧、深对流凝结加热东侧；而高空副热带高压出现在表面感热加热的东侧。

赤道中太平洋对流活动与西太平洋副高西伸的时延相关分析

采用交叉小波与相干小波变换方法,利用NCEP/NCAR再分析资料和NOAA卫星观测的外逸长波辐射(OLR)资料,在多年平均资料分析的基础上,选择2005和2006年夏季西太平洋副高的西伸过程进行了诊断分析,重点讨论了赤道中太平洋地区的对流活动对西太平洋副高西伸与维持的影响与关联。结果表明,7月中旬到8月中旬间,赤道中太平洋地区的对流活动通常表现出半月左右的准周期振荡,与副高活动具有相似的时频结构和周期特征,且前者对后者存在着约一个周期的超前影响,两者的这种时延相关性表现出较好的预报意义;运用大气视热源和全型垂直涡度方程,讨论了赤道中太平洋地区对流活动引起的经向加热异常对副高西伸的影响,指出由于异常的非绝热加热在副高西伸区域产生异常的反气旋性涡度输送,进而影响和制约副高形态和位置的变异。

江淮流域持续性强降水期间西太副高位置变异与非绝热加热的关系

采用NCEP/NCAR逐日再分析资料及全国740站逐日降水资料,讨论了江淮流域持续性强降水期间西太平洋副高位置变动特征及其与非绝热加热的关系。通过个例合成研究发现:副高位置变异与强降水持续期间大气非绝热加热关系密切。强降水持续期间,副高北侧的江淮流域和西侧的孟加拉湾北部地区均存在强烈的视热源和视水汽汇。强降水发生前3 d,江淮流域Q1z开始增大,到降水发生后2 d的Q1z达到最大,尔后逐渐减小,降水结束后变化趋于平缓,此期间不利于副高北抬;此外,强降水发生前2 d,孟加拉湾北部地区Q1z开始增大,降水发生后1 d达最大,副高逐渐西伸,此后,Q1z减小,副高相应有所东退。根据全型垂直涡度倾向方程,对流层中层,江淮流域非绝热加热的垂直变化有利于副高北侧气旋性涡度增长,阻碍副高北进,有利于雨带在江淮流域维持,形成持续性降水;孟加拉湾北部地区非绝热加热的垂直变化有利于副高西侧反气旋涡度增加,可能是诱导副高西伸的原因之一。

“05.6”华南强降水期间副热带高压活动与加热场的关系

采用NCEP/NCAR再分析逐日资料,根据全型垂直涡度倾向方程,研究2005年6月华南强降水期间西太平洋副热带高压(副高)位置变动特征及其与加热场的关系。结果表明,西太平洋副高位置变化和副热带地区的非绝热加热有密切关系。与气候平均状况相比,2005年6月副高北侧的加热区很强,而南侧赤道辐合带(ITCZ)没有相当强度的对流;伴随着副高北抬,其南侧均有明显的对流潜热加热向北伸展。副高西侧的加热基本上都大于副高纬带内的加热,副高的每一次西伸都伴随着西侧加热的显著增强,并且加热增强先于副高西伸。对流层中层,副高北侧非绝热加热率的垂直变化基本上都大于气候平均值,不利于副高北进;而南侧加热率的垂直变化均小于多年平均,有利于副高南侧反气旋性涡度异常增长,从而有利于副高南退。2005年6月下旬副高西伸之前,副高西侧非绝热加热率的垂直变化基本上都高于气候平均状况,有利于副高西侧反气旋涡度增加,从而诱使副高随后西伸;而东侧加热率的垂直变化大多数时间都低于气候平均状况,使得副高东侧气旋性涡度增加,有利于副高西伸,对流层低层也具有类似特点。因此在南北两侧加热和东西两侧加热的共同作用下,2005年6月副高位置较常年偏南偏西,从而有利于雨带在华南地区维持。

全型垂直涡度倾向方程的另一导出形式

地球大气运动同时满足牛顿第二定律与热力学第一定律,利用大气动力与热力方程对热力与动力变量的联系,直接将变形处理后的大气运动方程(涡度方程)与热力学方程结合起来,导出了显式包含热力与动力作用的全型垂直涡度倾向方程。

2008年登陆我国热带气旋异常的成因分析

利用NCEP/NCAR再分析资料和美国NOAA向外长波辐射(OLR)等资料,对2008年登陆我国热带气旋活动具有初台登陆早、秋台集中、登陆热带气旋比例高等特点及其成因进行了初步分析。结果表明,南半球冷高压发展引发的越赤道气流增强,使得赤道西风加强并向东延伸,热带辐合带对流活跃,有利于热带气旋生成;并且,在中纬度地区冷空气活动不频繁、西南季风涌活跃、副高位置偏北偏西等背景条件配合下,登陆热带气旋多而集中。运用大气视热源和全型垂直涡度倾向方程,发现热带辐合带增强北推,使得热带气旋接连产生,强降水产生的非绝热加热异常,促使副高位置发生显著北抬和西伸。当一个时期生成的热带气旋多而集中,副高的这种异常状态就会维持,从而造成这一时期热带气旋西行,频繁登陆我国。

春末夏初南亚高压活动与青藏高原及周边热力强迫的关系

利用1983—2012年NCEP/NCAR逐日再分析资料,探讨了5—6月南亚高压移上青藏高原的环流场的气候平均特征及其与青藏高原及邻近地区大气加热场的关系。结果表明:南亚高压从中南半岛北部向西北方向移动并于第33候移上青藏高原,恰好与高原南坡成为亚洲南部主要热源中心的时间相一致,且高原南坡整层积分的大气视热源增加速度远快于孟加拉湾以南至中南半岛,这可能是南亚高压移上高原的原因之一。同时采用简化后的全型垂直涡度方程分析加热场和环流场的关系,发现相对涡度平流项和地转涡度平流项有利于南亚高压向西移动,非绝热加热垂直变化项有利于南亚高压向北移动,三项共同作用促使南亚高压向西北移动移上高原。

中国东部城市群发展对南海夏季风爆发影响的模拟研究

本文利用NCAR开发的CAM5.1(Community Atmosphere Model Version 5.1)模式,针对我国东部大规模城市下垫面发展对南海夏季风爆发的影响进行了数值模拟研究。结果表明我国东部大规模城市群发展可能使得南海夏季风提前1候爆发;机理分析表明:在南海夏季风爆发之前,中国东部城市群发展引起的陆面增温,使得南海及其附近地区南北温差提前逆转、中国东部区域海平面气压降低,导致中南半岛到南海地区西南气流加强,中南半岛到南海地区降水增加,而凝结潜热垂直变化强迫出的异常环流,促进了南亚高压的加强及提前北跳,相伴随的高层抽吸作用有助于季风对流的建立和西太平洋副高的减弱东撤,从而形成了有利于南海夏季风爆发的高低层环流条件,导致南海夏季风提前爆发。另外,观测结果表明1993年之后南海夏季风爆发的日期相对上一个年代明显提前约2候,城市化快速发展阶段与南海夏季风爆发的年代际变化存在时间段的吻合,表明城市下垫面发展可能是南海夏季风提前爆发的原因之一。

2018年5月江苏极端降水事件发生前副热带高压异常及原因分析

本文利用NCEP/NCAR提供的2.5°× 2.5°全球再分析数据,以2018年5月江苏两次极端降水事件发生前副高异常变化为研究对象,根据全型涡度方程定量计算了凝结潜热分布不均引起的涡源对副高迅速演变的诱发作用。研究发现,120°E处500 hPa 5月第1候副高脊线多年平均位置位于16°N附近,而2018年同期120°E的脊线则位于19°N附近,呈明显偏北的状态。2018年5月第1候东亚500 hPa位势高度距平场表现出南高北低的形态,有利于我国华东地区成为暖湿空气和干冷空气的交汇区,构成了江苏5月两次极端降水过程的有利环流背景。与对流层中层环流异常对应的是,同期115°~125°E之间850 hPa上8 g·kg ^-1 等比湿线位于28°N附近,较多年气候态偏北15°,强降水区内同期850 hPa比湿较往年偏多2~4 g·kg ^-1 ,相应距平百分率可达50%~75%。且110°~120°E之间θ se 的340 K等值线5月第1候多年气候态位于13°N以南,但2018年同期却偏北至25°N附近,暖湿气团北进有利于强降水的发生。副高西伸北抬前,副高主体西侧和北侧均有凝结潜热加热区存在,说明潜热加热与副高演变关系密切。垂直剖面表明600 hPa为凝结潜热加热中心,向上加热率随高度减小,因此500 hPa处潜热加热率垂直梯度为负,使得500 hPa成为负涡源所在。因凝结潜热分布不均产生的负涡源,1~2 d便可形成与副高自身十分接近的负涡度值,足以诱发副高突变,该时间尺度与副高真实演变时间相符。负涡源中与凝结潜热垂直分布不均相关的部分起主要作用,而与凝结潜热水平分布不均相关的部分同时期产生的负涡度最多仅为前者的1/3左右,对副高突然西伸的作用较小。与凝结潜热相关的负涡源作为引发西太平洋副高异变的可能原因,其与副高的关系仍需进一步研究。

暴雨过程对副热带高压变动的影响

给出了长江中下游暴雨期间经圈环流观测事实 ,指出在考虑垂直运动日变化之后 ,可清晰地看到暴雨次级环流下沉支的存在。全型涡度方程对暴雨个例的计算发现 ,非绝热加热中心西侧高空激发出负涡度 ,东侧为正涡度 ;在低层则刚好相反。

Intra-seasonal Features of an Extreme High Temperature Event in 2011 in Eastern China and Its Atmospheric Circulation

Based on the daily maximum air temperature(T_(max))data from the China Meteorological Data Network and the NCEP/DOE reanalysis data,the intra-seasonal circulation and evolution of an extreme high temperature event(EHTE)in the middle reaches of the Yangtze River(MYR)from August 9-21,2011 were explored,as well as the influence of diabatic heating on the position variation of the Western Pacific subtropical high(WPSH).Results show that the daily T_(max) in the MYR exhibits a vigorous intraseasonal oscillation(ISO)of 10-25 days in the extended summer of 1980-2018.The main factors affecting the EHTE in the summer of 2011 are the low-frequency wave train propagating southeastward in the mid-latitude of the upper troposphere and the low-frequency anticyclone moving northwestward in the lowlatitude of the mid-lower troposphere.The diagnosis of 925hPa thermodynamic equation indicates that the ISO features of the T_(max) in the core region is determined by the intra-seasonal variation of the adiabatic variation.In addition,the variations of the WPSH correspond well to the distribution of apparent heat source.In the early stage of the high temperature process,the apparent heat source in the north of the Bay of Bengal is a certain indicator for the westward extension of the WPSH.

RELATIONSHIPS BETWEEN THE POSITION VARIATION OF THE WEST PACIFIC SUBTROPICAL HIGH AND THE DIABATIC HEATING DURING PERSISTENT INTENSE RAIN EVENTS IN YANGTZE-HUAIHE RIVERS BASIN

By using NCEP/NCAR daily reanalysis data and daily precipitation data of 740 stations in China, relationships between the position variation of the West Pacific subtropical high (WPSH) and the diabatic heating during persistent and intense rains in the Yangtze-Huaihe Rivers basin are studied. The results show that the position variation of WPSH is closely associated with the diabatic heating. There are strong apparent heating sources and moisture sinks in both the basin (to the north of WPSH) and the north of Bay of Bengal (to the west of WPSH) during persistent and intense rain events. In the basin, Q 1z begins to increase 3 days ahead of intense rainfall, maximizes 2 days later and then reduces gradually, but it changes little after precipitation ends, thus preventing the WPSH from moving northward. In the north of Bay of Bengal, 2 days ahead of strong rainfall over the basin, Q 1z starts to increase and peaks 1 day after the rain occurs, leading to the westward extension of WPSH. Afterwards, Q 1z begins declining and the WPSH makes its eastward retreat accordingly. Based on the complete vertical vorticity equation, in mid-troposphere, the vertical variation of heating in the basin is favorable to the increase of cyclonic vorticity north of WPSH, which counteracts the northward movement of WPSH and favors the persistence of rainbands over the basin. The vertical variation of heating in the north of Bay of Bengal is in favor of the increase of anti-cyclonic vorticity to the west of WPSH, which induces the westward extension of WPSH.

1999年北京持续高温天气过程的诊断分析

利用北京观象台观测资料和NCEP/NCAR再分析数据,对1999年6月24日至7月2日北京一次持续性高温天气的演变和发展过程及非绝热加热作用对系统的影响进行诊断分析,结果表明:在此次高温天气发生前,欧亚大陆中高纬度环流经向度很大,欧洲北部和贝加尔湖以南为高压脊控制,中亚和我国东北地区则处于低压槽内。贝加尔湖南部的高压脊纬向延伸范围较广,在东移过程中长时间影响北京。随着贝加尔湖以南的高压脊逐渐东移,北京上空下沉增温与非绝热加热作用有所增强,北京逐渐受到高温天气影响。在高温天气发生的后半阶段,我国东北的低压槽入海后在120-130°E附近维持并发展,槽前非绝热加热率很大。从垂直方向来看,加热率在500h Pa以下随高度迅速增加,根据全型涡度方程,强烈的非绝热加热率垂直分布不均作为一个明显的涡度源区,对入海低压槽的稳定维持有显著的作用。而入海低压槽的稳定维持,又阻碍了华北高压脊的东移,使其在北京地区长时间稳定少动,为北京带来多日的持续性高温天气。

2009年夏季西太平洋副热带高压北抬原因初探

利用数值模式再分析数据和常规观测资料,分析研究2009年6 8月西太平洋副热带高压(以下简称副高)连续5次北抬至偏北位置,且异常稳定维持,造成江淮流域于旱少雨(空梅)之缘由。通过合成、相关等分析方法探讨西风带、副热带、热带主要大气环流系统之间的相互影响和作用,并利用全型涡度方程探讨剐高北抬和强度维持的主要机制。结果表明:(1)西风带波动的传播与副高变化关系密切,西太平洋副高的北抬过程起始于中段副高(140°～160°E)强度加强;(2)副高北抬之前孟加拉湾东部有明显的对流活动,对于副高的北抬和加强有一定的指示意义,而副高南侧的对流活动与副高北抬之间是一种伴随关系;(3)涡度场变化分析可知,副高北抬的关键因素是中高纬度槽脊变化引起的东亚沿海负涡度的增加。

2019年6月西太平洋副热带高压脊线位置异常的机制分析

以2019年6月为例,采用统计和诊断分析方法研究了夏季西太平洋副热带高压脊线位置的变化特征,并分析了其位置较6月气候平均状态偏南的可能机制。结果表明:虽然2019年6月西太平洋副热带高压脊线位置总体偏南,但其经向位置异常存在纬向差异,在150°E以西区域,西太平洋副热带高压脊线平均位置偏南,而在150°~160°E区域内,脊线位置反而偏北。西太平洋副热带高压脊线位置变化与其附近异常涡度的经向分布有很好的对应关系,2019年6月西太平洋副热带高压脊线位置出现异常的原因在于其附近出现的异常扰动引起的异常涡度,而由于异常涡度分布存在纬向差异,造成西太平洋副热带高压脊线经向位置异常也出现了纬向差异。经过尺度分析简化的全型涡度方程的诊断发现,异常非绝热加热在导致2019年6月西太平洋副热带高压位置总体偏南的过程中起到了关键作用,而动力因子则对150°E以东的西太平洋副热带高压脊线向北偏移的贡献更大。

Relationship Between the Western Pacific Subtropical High and the Subtropical East Asian Diabatic Heating During South China Heavy Rains in June 2005

Based on the daily NCEP/NCAR reanalysis data,the position variation of the western Pacific subtropical high（WPSH） in June 2005 and its relation to the diabatic heating in the subtropical East Asia are analyzed using the complete vertical vorticity equation.The results show that the position variation of the WPSH is indeed associated with the diabatic heating in the subtropical East Asian areas.In comparison with June climatology,stronger heating on the north side of the WPSH and relatively weak ITCZ（intertropical convergence zone） convection on the south side of the WPSH occurred in June 2005.Along with the northward movement of the WPSH,the convective latent heating extended northward from the south side of the WPSH.The heating to the west of the WPSH was generally greater than that inside the WPSH,and each significant enhancement of the heating field corresponded to a subsequent westward extension of the WPSH.In the mid troposphere,the vertical variation of heating on the north of the WPSH was greater than the climatology,which is unfavorable for the northward movement of the WPSH.On the other hand,the vertical variation of heating south of the WPSH was largely smaller than the climatology,which is favorable for the anomalous increase of anticyclonic vorticity,leading to the southward retreat of the WPSH.Before the westward extension of the WPSH in late June 2005,the vertical variation of heating rates to（in） the west（east） of the WPSH was largely higher（lower） than the climatology,which is in favor of the increase of anticyclonic（cyclonic） vorticity to（in） the west（east） of the WPSH,inducing the subsequent westward extension of the WPSH.Similar features appeared in the lower troposphere.In a word,the heating on the north-south,east-west of the WPSH worked together,resulting in the WPSH extending more southward and westward in June 2005,which is favorable to the maintenance of the rainbelt in South China.