1958年7月亚洲东南部西南季风区和太平洋信风区平均流场和平均经圈环流

亚洲东南部西南季风区和太平洋信风区环流特点有显著的不同。在季风区有南部下沉、北部高原地区上升的垂直季风环流,高层有东风急流,下层有达400毫巴高度的深厚的西南气流。在信风区、低纬度则存在着典型的Hadley环流,高层有夏季太平洋中部副热带西风急流,下部有东北信风,东风随高度减弱。 季风垂直环流的存在,进一步说明了季风形成的因子。     

亚洲季风区纬圈剖面内准40天周期振荡的环流结构及其演变

本文利用1979年FGGE LevelⅢb资料研究了30°E—150°W范围内赤道和15°N纬带两个剖面内的准40天周期振荡的环流和温度场结构,讨论了它们的变化及其与亚洲地区季风活跃和中断的关系。发现有以下结果:(1)亚洲季风槽内的上升气流不仅构成了强大的经向季风环流圈,同时在其两侧也形成了东、西向(纬偏异常)环流圈,并受到准40天周期扰动的显著影响。季风槽两侧的热力学结构显著不同。(2)15°N纬带上60°E以西的北非和沙特阿拉伯上空的下沉(上升)区域向东扩展至南海—菲律宾地区导致其东面(西面)的高(低)层东(西)风动量下(上)传,使得季风中断(活跃),引起130°E以西地区低层西风和其东面太平洋上空的高层东风发生相互作用。向东传播的正(负)温度扰动与强的上升(下沉)运动相结合使得这一地区成为准40天周期振动的能量源地。(3)在赤道剖面上,扰动风场的位相向东向上传播,准40天周期的扰动动能向扰动位能转换,西风动量向下传播,其动力学特性与开尔文波有明显的不同。      

北半球中低纬地区冬季平均垂直环流的某些特征

本文将继[1]之后,讨论北半球冬季中低纬地区的平均垂直环流。资料来源和计算方法与文献[2]相同,不过这里我们把计算区扩展到全北半球的中低纬地区。 1.北半球中低纬地区冬季平均经向垂直环流的特征在北非和南欧地区(10°W—50°E)的平均经向垂直环流图上(图略),30°N以南是一     

东亚和太平洋上空平均垂直环流----(一)夏季

本文利用中央气象局出版的《北半球高空气候图集》中的风场资料,计算了50°E—130°W,0°—50°N范围内,七月平均850mb—100mb各标准层上的垂直运动,分析了不同区域的经向和纬向垂直环流的特点。指出:夏季130°E以西的低纬度为巨大的西南季风环流区,此外在高原的南北两侧还各存在一较小的经向环流圈,影响着高原附近的天气和气候;160°E以东的中低纬度的海洋上空为经典的Hadley环流所控制,其强度和影响的范围自西向东递增;由于青藏高原地形及夏季的热源作用,使其与西半球,南半球和中东太平洋的天气系统产生遥相关;平均直接从青藏高原上升的气流对西太平洋副高的贡献不大,而平均从西边直接下沉到西太平洋副高的气流是从高原以东的大陆上升的。最后根据计算和分析结果给出了青藏高原及其邻近地区三维空间的垂直环流示意图。     

EI Nino现象对东亚夏季风环流影响的初步研究

本文分析了1971—80年发生在南美洲西海岸的EI Nino现象及其对东亚夏季风环流的影响。结果表明,1972和1976年为强的EI Nino年,而1971和1974年为显著的反EI Nino年。还指出,1—6月份南美西海岸的海温与7月份我国东部大部分地区夏季风呈负相关.在EI Nino年,主要环流的特征为:(1)西太平洋副热带高压脊线偏北,强度偏弱.(2)澳大利亚高压位置偏南。(3)赤道缓冲脊强大.ITCZ东伸到太平洋中部。南半球的信风在105°E附近越过赤道之后,于10°N折向东去,流入西太平洋.(4)印度次大陆季风中断.孟湾西南季风直接影响我国东部地区的分量极其有限,在反EI Nino年,上述各系统特征完全相反.我们认为,EI Nino现象的发生,引起夏季风环流系统的变动,最终影响到我国夏季风的强度,这是二者之间遥相关的一种可能过程.      

500毫巴环流指数、环流型及环流特征量

1.500毫巴月平均环流指数分亚欧地区(45—65°N、0—150°E)和亚洲地区(45—65°N、60—150°E),其计算公式, 其中φ_1、φ_2表示计算纬向环流指数Iz的纬度范围,Z_(1i)、Z_(2i)分别是在φ_1、φ_2两纬圈上第i点的500毫巴高度读数,L为分别在φ_1、φ_2纬圈上均匀取点进行高度读数的点数。计算经向环流指数Im时,先将所考虑范围分成n个小区,在m个纬圈上分别读取经度间距为Δλ的相邻两点间高度差ΔZi,然后进行计算(详见中央气象科学研究所《论文汇集》1965年9月)。这里所附的月平均环流指数值是根据上式计算的逐候平均环流指数,     

2003年淮河流域特大暴雨期间低纬环流分析

利用NCEP NCAR提供的OLR和气象要素场再分析资料 ,对 2 0 0 3年 6～ 7月淮河流域特大暴雨期间西南季风和东亚季风以及热带低纬地区环流的异常特征及其对梅雨暴雨的贡献进行了分析。结果表明 ,暴雨期间 ,长江流域附近地区维持准稳定的比常年明显偏强的南风带 ,北方冷空气亦比常年偏强 ;三次强降雨过程 ,低层均表现为稳定的强南风与阶段性增强的偏北气流的经向辐合。三次强降水过程中有两次 ,来自西北太平洋的东南气流的水汽输送占主导地位。异常环流分析表明 ,淮河流域强降雨时段 ,东南亚季风和南海季风异常偏弱 ;赤道西北太平洋地区东风气流比常年同期异常偏强。诊断分析认为 ,高原东部和南部地区对流活动比常年同期偏弱 ,80～1 1 5°E地区越赤道气流比常年异常偏弱 ,可能是西南季风异常偏弱原因。而偏强的WAKER环流可能是西北太平洋地区低纬地区东风异常偏强的原因。另外 ,印度尼西亚地区低层气流辐合异常偏强有利于副高的稳定和加强 ,进而使我国东南部地区长时间维持强异常偏强的东南气流 ,从而为淮河流域的持续暴雨提供了源源不断的来自南海和西北太平洋的暖湿气流     

青藏高原南侧经圈环流变化特征及其对降水影响分析

基于1979-2015年青藏高原(下称高原)地区气象观测站的逐日降水资料和ERA-Interim逐日再分析资料,分析高原南侧经圈环流的季节演变及年际变化特征,并讨论其对高原降水及水汽输送的影响。结果表明,高原南侧80°E-90°E范围存在前季风环流、季风环流、Hadley环流的季节演变,前季风环流有-0. 377 s~(-1)·(10a)~(-1)减弱的趋势,季风环流有0. 524 m·s~(-1)·(10a)~(-1)显著增强趋势。在90°E-105°E范围存在季风环流和Hadley环流季节转换,季风环流存在0. 413 m·s~(-1)·(10a)~(-1)的增强趋势。基于各经圈环流开始、结束时间的定义,发现在80°E-90°E,前季风环流建立的时间有推迟而结束时间有提前的现象,其维持时间出现每10年-1. 47候的缩短趋势。在90°E-105°E,季风环流维持时间增长,Hadley环流维持时间缩短。前季风环流增强使得高原水汽辐散区辐散增强,水汽辐合区辐合增强,高原西南侧有东北向水汽输送增强,而高原西北侧有西南向水汽输送增强。夏季季风环流增强,高原南部至孟加拉湾地区自南向北的经向水汽输送显著增强,印度洋向高原输送的西南向水汽通量明显增加。前季风环流增强,春季高原中部及西南部降水减少,而东南部和北部降水增加。夏季季风环流增强时,高原南侧上升支增强,高原南部降水增加,而高原北部降水出现减少。     

近二十年北太平洋700毫巴月平均环流型

为了进一步探讨北太平洋高压进退活动及我国大部分地区旱涝变化的规律,我们对近廿年(1954—1973年)北太平洋区(15—65°N;30°N以北120°E—120°W,30°N以南100°E一100°W)700毫巴月平均高度的环流形势进行分析。初步发现:(1)在不同的旱涝年份,北太平洋700毫巴的月平均环流形势分别具有一定的特点。(2)北太平洋区700毫巴月平均环流分布与演变的一些特征与中国海附近副热带高压(以下简称副高)的进退活动以及北太平洋海温的变化具有较好的相互关系。(3)逐年与逐月之间,北太平洋700毫巴月平     

越赤道气流通道上的经向垂直环流结构

本文运用1981年夏季月份,各标准等压面上格点风资料,分析了东半球低纬地区(40°—180°E、30°N—30°S),越赤道气流通道上各种物理量场分布和经向垂直环流。从而揭示了越亦道气流和季风环流及哈德莱环流相互之间的关系。     

东亚夏季风指数的年际变化与东亚大气环流

文中从夏季东亚热带、副热带环流系统特点出发 ,定义了能较好表征东亚夏季风环流年际变化的特征指数 ,并分析了东亚夏季风指数的年际变化与东亚大气环流及夏季中国东部降水的关系。文中定义的东亚夏季风指数既反映了夏季东亚大气环流风场的变化特征 ,也较好地反映了夏季中国东部降水的年际变化特征。此外 ,还探讨了东亚夏季风指数变化的先兆信号     

Spring Arctic Oscillation-East Asian summer monsoon connection through circulation changes over the western North Pacific

In the present study the links between spring Arctic Oscillation (AO) and East Asian summer monsoon (EASM) was investigated with focus on the importance of the North Pacific atmospheric circulation and sea surface temperature (SST). To reduce the statistical uncertainty, we analyzed high-pass filtered data with the inter-annual time scales, and excluded the El Ni?o/Southern Oscillation signals in the climate fields using a linear fitting method. The significant relationship between spring AO and EASM are supported by the changes of multi-monsoon components, including monsoon indices, precipitation, and three-dimensional atmospheric circulations. Following a stronger positive spring AO, an anomalous cyclonic circulation at 850?hPa appears in southeastern Asia and the western North Pacific in summer, with the easterly anomalies spanning from the Pacific to Asian continent along 25°N?C30°N and the westerly anomalies south of 15°N. At the same time, the summer western North Pacific subtropical high becomes weaker. Consistently, the positive precipitation anomalies are developed over a broad region south of 30°N stretching from southern China to the western Pacific and the negative precipitation anomalies appear in the lower valley of the Yangtze River and southern Japan. The anomalous cyclone in the western North Pacific persisting from spring to summer plays a key role in modulating EASM and monsoon precipitation by a positive air-sea feedback mechanism. During spring the AO-associated atmospheric circulation change produces warmer SSTs between 150°E?C180° near the equator. The anomalous sensible and latent heating, in turn, intensifies the cyclone through a Gill-type response of the atmosphere. Through this positive feedback, the tropical atmosphere and SST patterns sustain their strength from spring to summer, that consequently modifies the monsoon trough and the western North Pacific subtropical high and eventually the EASM precipitation. Moreover, the SST response to AO-circulation is supported by the numerical simulations of an ocean model, and the anomalous atmospheric circulation over the western North Pacific is also reproduced by the dedicated numerical simulations using the coupled atmosphere?Cocean model. The observation evidence and numerical simulations suggest the spring AO can impact the EASM via triggering tropical air-sea feedback over the western North Pacific.     

Northwest Pacific tropical cyclone activity and July rainfall over India

Summary In 2002, India had experienced one of the most severe droughts. The severe drought conditions were caused by the unprecedented deficient rainfall in July 2002, in which only 49% of the normal rainfall was received. One of the major circulation anomalies observed during July 2002, was the active monsoon trough over Northwest (NW) Pacific and enhanced typhoon activity over this region. The present study was designed to examine the long-term relationships between Tropical Cyclone (TC) activity over NW Pacific and monsoon rainfall over India in July. A statistically significant negative correlation between TC days over NW Pacific and July rainfall over India was observed. Spatial dependence of the relationship revealed that TCs forming over NW Pacific east of 150° E and moving northwards have an adverse effect on Indian monsoon rainfall. It was observed that TCs forming over the South China Sea and moving westwards may have a positive impact on monsoon rainfall over India. Enhanced TC activity over NW Pacific during July 2002 induced weaker monsoon circulation over the Indian region due to large-scale subsidence.     

东亚夏季风建立过程中的大气能量变化

本文利用1980、1981年4—6月资料,分析了0°—25°N、95°—120°E区域中的大气能量变化。发现在东亚夏季风建立过程中,该区域中能量水平收支和分布均发生了明显的变化,并能较好地反映出东亚夏季风的建立早晚和强弱差异。对总能量各项的计算结果表明:潜热能是东亚夏季风建立过程中的一个重要影响因子。 文章还初步研究了东亚夏季风建立前期,中低纬环流之间相互作用的动力学表现。指出90°—125°E之间,前期越过35°N向南输送的涡动动量对东亚夏季风建立具有触发作用。      

ENERGY BALANCE IN 40－50 DAY PERIODIC OSCILLATION OVER THE ASIAN SUMMER MONSOON REGION DURING THE 1979 SUMMER

Based on calculations of data from FGGE Level III b, a discussion is made of the energy balance in the 40－50 day periodic oscillation over the Asian monsoon region during the 1979 summer. It is found that the main source of 40－50 day periodic perturbation is the monsoon region extending from central South Asia to Southeast Asia. In the upper layer over the North Pacific subtropical area (10－20oN, 150oE－150oW) pres-sure work turns into kinetic energy that maintains 40－50 day periodic perturbation associated with the variation in position and intensity of the mid-Pacific trough. The mean energy budget in the three-dimensional space (0－30oE, 30oE－150oW, 100－1000 hPa) indicates that the 40－50 day periodic perturbation transports kinetic energy to a seasonal mean and a transient perturbation wind field.     

1991 年夏暴雨期间Walker 环流和Hadley 环流的特征

该文分析了1991年7月中国江淮暴雨洪水期间赤道太平洋沃克环流及沿115°E哈得莱环流的逐日演变特征。结果发现在暴雨时期赤道东风减弱，西风加强，反哈得莱环流（即季风环流）在中国东部上空加强。在暴雨期间，高低空散度风场的分析指出，在低空出现明显的散度风越赤道气流，而在对流层上部出现散度风的流出。     

季风湿润区夏季水汽收支的年代际变化特征

采用1983—2002年NCEP/NCAR再分析资料和我国660站降水资料,对我国东部季风湿润区夏季水汽收支变化与大气环流和我国降水异常特征的关系进行研究。结果表明:20世纪80—90年代夏季水汽收支时间序列表现出明显的年代际变化增加趋势,与降水时间序列的相关系数为0.71;水汽收支高值、低值年代不仅能够指示季风湿润区经向风的异常变化,还能够指示东亚夏季风的强弱和降水异常变化。合成的水汽输送年代际异常在东亚—西太平洋区表现为4个异常环流,异常水汽通量辐合区位于长江流域及以南地区。水汽收支高值年代,亚洲大陆高纬度地区低压偏弱,大陆表面温度及西太平洋海温偏高,我国东部沿海盛行异常偏南风,低层气流辐合、高层气流辐散强,垂直上升运动强烈;低值年代则相反。合成的经向水汽收支占总收支的71.3%,合成的异常降水量最大达100 mm以上。     

东亚夏季风的变化与中国降水

本文分析了1951—1980年东亚夏季风的强弱变化及其与我国降水分布的关系,发现夏季风强弱不同的时期,我国降水分布有明显差异。同时研究表明,随季风强弱的变化,相应的行星尺度环流亦发生明显改变。最后对夏季风强弱变化的可能原因进行了讨论.      

Impact of the western North Pacific subtropical high on the East Asian monsoon precipitation and the Indian Ocean precipitation in the boreal summertime

The western North Pacific subtropical high (WNPSH) is a crucial component of the East Asian summer monsoon (EASM) system and significantly influences the precipitation in East Asia. In this study, distinguished role of WNPSH on the EASM and Indian Ocean monsoon (IOM) are investigated. Based on the boreal summer mean field of 850-hPa geopotential height and its interannual variability, the WNPSH index (WNPSHI) is defined by the areaaveraged geopotential height over the region [110°–150°E, 15°–30°N]. The WNPSHI is significantly related to the precipitation over the East Asian monsoon (EAM) region [105°–150°E, 30°–40°N] and IOM region [70°–105°E, 5°–15°N]. Rainfalls over these two regions have good correlation with WNPSH developments and the geopotential height fields at 850 hPa related to the EAM precipitation and IOM precipitation have remarkably different teleconnection patterns in boreal summer. These features exhibit that EAM and IOM precipitations have different type of development processes associated with different type of WNPSH each other. Focusing on the relationships among the EAM precipitation, IOM precipitation, and the WNPSH variabilities, we assume that WNPSH and EAM precipitation are usually fluctuated simultaneously through the sea surface temperature (SST)-subtropical ridge-monsoon rainfall feedback, whereas the IOM precipitation varies through the different process. To clarify the relationships among WNPSH, EAM, and IOM, two cases are selected. The first one is the case that all of WNPSH, EAM, and IOM are in phase (WE(+)I(+)), and the second one is the case that WNPSH and EAM are in phase and WNPSH/EAM and IOM is out of phase (WE(+)I(?)). These two cases are connected to the thermal forcing associated with SST anomalies over the eastern Pacific and Indian Ocean. This different thermal forcing induces the change in circulation fields, and then anomalous circulation fields influence the moisture convergence over Asian monsoon regions interactively. Therefore, the monsoon rainfall may be changed according to the thermal conditions over the tropics.