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1.
西北太平洋热带气旋频数的年际、年代际变化及预测 总被引:4,自引:0,他引:4
利用1950-2009年60 a的热带气旋资料、NOAA海温、NCEP再分析资料及74项环流指数等资料,研究了西北太平洋热带气旋频数的年际、年代际变化特征,结果表明,西北太平洋热带气旋生成频数既有显著的年际变化,同时也存在明显的年代际变化。自1950年以来,西北太平洋热带气旋频数经历了一个先增加再减少的过程,其中转折点在20世纪70年代中后期,与之相对应,热带气旋路径频数也呈现明显年代际变化。在此基础上,通过分析前期春季海温场、大气环流异常及环流指数与夏季(6-10月)热带气旋生成频数的相关关系,选取了影响夏季西北太平洋热带气旋活动频数的预测因子,建立了一个夏季西北太平洋热带气旋生成频数的多元回归预测模型。检验结果表明,该模型能较好地拟合1951-2003年夏季西北太平洋热带气旋生成频数的年际变化,拟合率为0.6。对2004-2009年夏季热带气旋生成频数的独立样本预测试验表明,该模型对夏季西北太平洋热带气旋活动频数具有较好的预测能力,可以为热带气旋业务预报提供一定参考。 相似文献
2.
《广东气象》2016,(3)
利用1967—2013年影响斗门热带气旋的频数、强度以及海温、西太平洋副热带高压指数等资料,采用M-K法、Yamamoto法、功率谱分析以及相关方法分析了影响斗门热带气旋的气候特征及其与太平洋海温、西太平洋副热带高压的关系。结果表明:(1)影响斗门热带气旋的频数有明显的年代际变化,20世纪80年代初之前为多热带气旋时期,80年代初到2007年期间为少热带气旋时期。(2)4—12月皆有热带气旋影响斗门,其中7—9月最多,影响也最为严重。(3)影响斗门的热带气旋频数存在2~3年左右的显著周期。(4)影响斗门的热带气旋强度存在2~4年左右的显著周期,但长期变化趋势不明显。(5)太平洋海温对热带气旋的频数和强度的影响有不同的关键区;而副热带高压的面积、西伸脊点位置主要影响热带气旋的频数,其脊线位置、588 dagpm线北界位置则影响热带气旋的强度。 相似文献
3.
使用1951—2013年NOAA OLR、NCEP/NCAR风场和高度场再分析资料、中国气象局热带气旋资料,分析2013年影响广西热带气旋数量偏多的原因。结果表明:2013年6—9月西太平洋副热带高压明显偏强,西伸脊点明显偏西,脊线略偏北,同时副热带高压南侧对流活跃,降水过程潜热释放有助于副热带高压位置偏北,这种形势非常有利于热带气旋向广西移动。索马里越赤道气流强劲,在南海及菲律宾与北太平洋反气旋西南侧的东南气流相遇,形成季风槽,非常有利于热带气旋生成频数偏多。热带低频强对流带在印度洋和西太平洋活动频繁,并分别向东向西移动;赤道东太平洋海温偏低;哈得来和沃克环流较常年偏强,沃克环流上升支位置偏西,这些也可能是2013年影响广西热带气旋数量偏多的原因之一。 相似文献
4.
利用有限混合模型FMM聚类算法,将1951—2012年夏秋季(6—11月)登陆我国的热带气旋(Tropical Cyclone,TC)路径数据集分为三类,并对三类不同路径TC的季节变化、发生频数、环流形势等特征进行对比分析。研究表明,每类TC存在明显的特征差异:1)在夏季,第一、二类TC出现频数高于第三类,但在秋季第三类TC发生频数最高。2)第一类TC生成位置偏北,强度较强,生命史较长,路径略有向北发展的趋势,影响区域最广;第二类TC生命史最短,主要影响我国两广、福建一带;第三类TC生命史最长,路径略向西北方向发展。3)第一类TC在生成和消亡时的辐合程度最强,且副高脊线西伸脊点位置偏北;第二类TC在消亡时低层辐合最弱,且副高脊线西伸脊点位置偏西;第三类TC在生成时纬向风垂直切变最强,且副高脊线西伸脊点位置偏东南。 相似文献
5.
应用1884—2003年影响福建的热带气旋资料, 采用突变分析、最大熵谱分析、连续小波变换以及正交小波变换等方法研究百余年来影响福建热带气旋频数变化的多时间尺度特征及其异常年份的海气背景场特征。结果表明:百余年来福建经历了3次少台期和2次多台期, 影响福建热带气旋频数具有准13年、准4年和准2.5年的振荡周期, 1971年为年频数变化的突变点; 影响福建热带气旋频数近百年呈弱的上升趋势, 但近十几年略微下降, 未来有偏多的趋势; 影响福建热带气旋异常偏多 (少) 的年份, 夏季500 hPa高度场上, 鄂霍次克海地区位势高度偏低 (高), 从高纬到低纬呈“-+-”(“ +-+”) 的距平型, 纬 (经) 向环流占优势, 西风带低槽偏北 (南), 副热带高压北界偏北 (南), 副热带高压脊线偏北 (南); 赤道中、东太平洋为明显的带状负 (正) SSTA距平区, 同时西太平洋热带气旋主要源区和西北太平洋上皆为正 (负) SSTA距平。由此可见, 影响福建热带气旋频数多寡与西太平洋热带气旋生成区的海温有关, 同时大气环流系统的位置和强弱对热带气旋路径的变化起着关键性作用, 从而使影响福建热带气旋频数的变化。 相似文献
6.
西北太平洋热带气旋频数变化特征及其与海表温度关系的进一步研究 总被引:6,自引:2,他引:4
根据西北太平洋56年(1949—2004年)热带气旋系列资料,分析了不同级别的热带气旋频数多年变化的统计特征及其与太平洋海表温度(SST)的关系。结果表明: 西北太平洋热带气旋频数主要的变化特征是年际和年代际变化,不同等级的热带气旋频数变化特征存在差异,但就变化趋势而言随时间减少,均无明显因全球增暖导致的热带气旋增加的现象。对不同海区分别讨论SST对热带气旋的影响,从存在的超前滞后相关发现赤道东太平洋SST负异常会引起更多的热带气旋频数,而且强度越大的热带气旋受到海温的影响越早;更多的热带气旋频数又会引起西北太平洋的SST负异常,热带气旋强度越大产生负异常的周期越短;北太平洋中部的SST与热带气旋的频数存在较好的正相关关系。这些关系体现了热带气旋强涡旋风场导致局地海洋上层混合作用和太平洋海气耦合经向模态对热带气旋的影响。 相似文献
7.
本文利用ERA5 1979-2019年逐月大气再分析资料计算南北印度洋热带气旋生成指数,并和IBTrACS观测数据进行比较,探讨用热带气旋生成指数研究南北印度洋热带气旋变化特征的适用性.研究发现热带气旋生成指数能较好地刻画南北印度洋热带气旋的空间分布特征、北印度洋热带气旋个数月变化的双峰结构,以及南印度洋比北印度洋热带气旋发生概率高等特征.最新的IBTrACS v4.0观测资料显示,40年来北印度洋热带气旋每年总生成个数平均每10年增加1.3个,频数的增加主要来源于热带低压和热带风暴,而南印度洋热带气旋每年总生成个数每10年减少2.8个.热带气旋生成指数能很好地描述北印度洋热带气旋生成个数的上升趋势,但对南印度洋热带气旋生成个数趋势的刻画与观测不一致,可能原因需要进一步深入研究. 相似文献
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9.
使用1951-1997年影响广西的热带气旋年频数与前期和同期的海温场、500hPa高度场进行相关分析,结果表明,赤道太平洋海区的海温与影响广西的热带气旋年频数有密切关系,厄尔尼诺年副高强度偏强,西伸脊点偏西,影响广西的热带气旋偏少,拉尼娜年副高偏弱,影响广西的热带气旋偏多.然后挑选相关系数高的高相关区,以其为预报因子,利用相似分析方法和逐步回归方法对影响广西的热带气旋年频数作预报试验.结果表明,用相似离度方法做预报时,第1相似对特多特少年的预报基本可信,而第2、3相似预报不稳定;用逐步回归建立的预报方程平均拟合误差约为1个,1998和1999年的试报效果较好. 相似文献
10.
利用海气耦合模式预测的大尺度环流进行热带气旋年频数的预测试验 总被引:2,自引:1,他引:1
基于对热带气旋生成频数和大尺度环流相关关系的分析,利用SINTEX-F海气耦合模式预测的大尺度大气环流信息,通过提取模式预测较好与热带气旋生成密切相关的有用信息,建立了一个基于动力模式预测结果的南海和西太平洋热带气旋年频数预测模型,并对1982—2010年的热带气旋生成频数进行预测试验与检验。SINTEX-F海气耦合模式能够较好预测部分与热带气旋生成密切相关的大尺度环流特征,其中包括热带气旋活动区域的海平面气压、对流层风垂直切变、850 hPa热带辐合带和850 hPa 90 °E附近的越赤道气流。利用这些大尺度环流建立的预测因子与热带气旋生成频数有很好的相关关系,利用这些预测因子建立的多元回归预测模型对热带气旋频数的拟合率为0.8(相关系数,超过99.9%的信度检验)。预测模型的交叉检验结果表明模型整体预测效果较好。交叉检验预测结果与实况热带气旋频数的相关为0.71(超过了99.9%的信度检验),距平同号率为82.8%。但模型对热带气旋异常年的预测误差较大。 相似文献
11.
江南南部初夏雨季的降水和环流气候特征 总被引:3,自引:0,他引:3
基于1961~2010年气象台站逐日降水资料、同期美国NCEP/NCAR的逐日再分析格点资料,通过气候平均、REOF分析、聚类分析等方法,分析了江南地区初夏降水的地域性和时段性特征,及西太平洋副高和高、低空急流等大气环流的相应演变过程。结果发现:(1)江南南部27.5°~29.5°N存在一个独立于华南前汛期和江淮梅雨的初夏雨季,该雨季平均发生时间为6月11~30日,比江淮梅雨早约8天左右。(2)西太平洋副高的西伸东退是江南南部初夏雨季发生发展的重要环流背景,6月第2候副高发生突变性加速西伸之后雨季开始,雨季期间850 hPa副高西伸脊点基本稳定在最西位置即133°E附近,6月第6候副高东退北抬后雨季结束。(3)低层急流大风带的形成和位置是江南南部初夏雨季阶段的重要动力条件,印度洋和孟加拉湾向东北延伸的低层急流与西太平洋副高西北侧的气流连通形成低层急流大风带,并与北侧上空的高空急流耦合,降水集中区位于低层急流大风带左侧、高空急流入口区右侧。 相似文献
12.
华北雨季开始早晚与大气环流和海表温度异常的关系 总被引:2,自引:0,他引:2
本文利用国家气候中心的1961~2016年华北雨季监测资料、美国国家环境预报中心/大气研究中心(NCEP/NCAR)的大气再分析资料、NOAA海表温度资料,分析了华北雨季开始早晚的气候特征,然后利用合成分析、回归分析等方法,研究了华北雨季开始早晚与大气环流系统和关键区域海表温度的关系。结果表明,56 a来华北雨季开始最早在7月6日,最晚在8月10日,1961~2016年华北雨季开始平均日期是7月18日。华北雨季开始时间具有显著的年际变化,但雨季发生早晚的长期变化趋势不太明显。华北雨季开始早晚与西太平洋副热带高压(简称副高)、东亚副热带西风急流、东亚夏季风等环流系统的活动关系密切,当对流层高层副热带西风急流建立偏早偏强,中层西太平洋副高第二次北跳偏早,低层东亚夏季风北进提前时,华北雨季开始偏早,反之华北雨季开始偏晚。华北雨季开始早晚与春、夏季热带印度洋、赤道中东太平洋海表温度关系显著且稳定,当Ni?o3.4指数和热带印度洋全区海表温度一致模态(IOBW)为正值时,贝加尔湖大陆高压偏强,副高偏强偏南,东亚夏季风偏弱,导致华北雨季开始偏晚;当海表温度指数为负值时,则华北雨季开始偏早。 相似文献
13.
Interdecadal Variations of the Western Pacific Subtropical High and Surface Heat Flux over East Asia and Their Relationship 
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下载免费PDF全文 The interdecadal variation of intensity of the western Pacific subtropical high(WPSH) during the period 1951-2001 is studied by using data from the National Climate Center(NCC),China Meteorological Administration.The characteristics of the circulations at 500 hPa and the surface heat flux over East Asia are also analyzed based on the NCEP/NCAR monthly reanalysis data.The results reveal that the WPSH and the circulations exhibit interdecadal variations around 1978,with enhancing intensities.The interseasonal persistence of the WPSH intensity alters correspondingly to some extent,which is more significant during 1978-2001 than during 1951-1978.The surface heat flux over East Asia also displays a remarkable interdecadal variation,which leads that of the WPSH intensity.The key variation areas of the surface sensible heat flux(SSHF) are mainly located over the eastern and western Tibetan Plateau around the late 1960s.However,the difference of the SSHF between the eastern and western Plateau exhibits a change in the mid 1970s,close to the time of the abrupt climate change of the WPSH intensity.The SSHF of the Plateau stably increases in the west and decreases in the east before the mid-late 1960s,while it stably increases in the east and decreases in the west after the mid-1970s.On the other hand,the key variation area of the surface latent heat flux(SLHF) is mainly situated over the West Pacific(WP),where the SLHF anomaly in spring changes from positive to negative in the south before 1978,but from negative to positive in the north after 1978;while in summer it turns from positive to negative all over the WP after 1978.The interdecadal variation of SLHF in both spring and summer corresponds well to the interdecadal variation of the WPSH intensity in the same season.The notable correlation between the WPSH intensity and SSHF(or SLHF) maintains without any change although each of these qnantities varies on the interdecadal scale. 相似文献
14.
2012年华南前汛期降水特征及环流异常分析 总被引:5,自引:1,他引:4
2012年华南前汛期于4月第2候开始,6月第5候结束。前汛期降水经历了三个不同的阶段:第一阶段是4月第2候至5月第3候的降水集中期(锋面降水),江南大部和华南大部降水偏多25%以上,第二阶段是5月第4候至6月第2候的少雨期,华南中部和东部降水偏少50%以上,第三阶段是6月第3—5候的第二个降水集中期(季风降水),江南东南部至华南中西部降水偏多50%以上。对各阶段大气环流距平场的分析结果表明:华南前汛期开始后,偏强的乌拉尔山高压脊导致南下的冷空气偏强,偏强的低层副热带高压使得我国南方为整层水汽输送的异常辐合区,两者共同导致华南前汛期第一阶段的锋面降水较常年同期偏多;南海夏季风在爆发后偏弱和西北太平洋副热带高压(以下简称副高)持续3候异常偏北是导致第二阶段前汛期降水明显偏少的主要原因;第三阶段,南海夏季风异常偏强,副高南落并增强,以及孟加拉湾季风槽的偏强使得华南前汛期此阶段的季风降水偏多。 相似文献
15.
Predicting Western Pacific Subtropical High Using a Combined Tropical Indian Ocean Sea Surface Temperature Forecast 下载免费PDF全文
下载免费PDF全文 Weather and climate in East China are closely related to the variability of the western Pacific subtropical high(WPSH), which is an important part of the Asian monsoon system. The WPSH prediction in spring and summer is a critical component of rainfall forecasting during the summer flood season in China. Although many attempts have been made to predict WPSH variability, its predictability remains limited in practice due to the complexity of the WPSH evolution. Many studies have indicated that the sea surface temperature(SST) over the tropical Indian Ocean has a significant effect on WPSH variability. In this paper, a statistical model is developed to forecast the monthly variation in the WPSH during the spring and summer seasons on the basis of its relationship with SST over the tropical Indian Ocean. The forecasted SST over the tropical Indian Ocean is the predictor in this model, which differs significantly from other WPSH prediction methods. A 26-year independent hindcast experiment from 1983 to 2008 is conducted and validated in which the WPSH prediction driven by the combined forecasted SST is compared with that driven by the persisted SST. Results indicate that the skill score of the WPSH prediction driven by the combined forecasted SST is substantial. 相似文献
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本文利用1951—2010年NCEP/NCAR再分析月平均资料研究了热带海表面温度对南亚高压与西太平洋副热带高压发展变化的影响,得到以下主要结论:在两高压强年与暖海温年(两高压弱年与冷海温年)里,冬、春两季赤道印度洋、太平洋海温距平呈现显著的正?负?正(负?正?负)的厄尔尼诺(拉尼娜)现象,中南半岛附近的对流层高层产生异常西风(东风)气流,有利于(不利于)南侧异常反气旋环流的产生,从而促进(阻碍)南亚高压发展;菲律宾海域的对流层产生异常下沉(上升)气流,有利于(不利于)西北侧异常反气旋环流的产生,从而促进(阻碍)低层西太副高的发展。夏季,热带印度洋的暖海温(冷海温)有效地增加(降低)了当地的对流效应,使大气对流层温度增暖(减低),影响南亚高压与西太平洋副热带高压的发展。 相似文献
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Relationship Between the Western Pacific Subtropical High and the Subtropical East Asian Diabatic Heating During South China Heavy Rains in June 2005 下载免费PDF全文
下载免费PDF全文 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. 相似文献
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晚春初夏西太平洋副热带高压南撤过程的气候学特征 总被引:8,自引:3,他引:5
利用1979—2006年多年平均逐日NCEP/NCAR再分析资料、NOAA的OLR和逐候CAMP降水资料,从气候学角度探讨了晚春初夏季节转换时期,西太平洋副热带高压(副高)脊线位置变化及其与亚洲夏季风爆发的关系。发现晚春初夏时期西太平洋副高在向北移动过程中存在一次显著的南撤过程,之后西太平洋副高发生第一次北跳,南撤主要发生在对流层高层和低层,南撤生命期可达2周,且高层的南撤过程结束时间比低层的南撤过程开始时间早约1旬,这为预测低层副高南撤及其第一次北跳提供了有意义的前期信号。低层西太平洋副高南撤的同时伴随着一次显著东退过程。在低层副高南撤结束后(约5月底),由于气温经向梯度的变化使副高脊轴倾斜发生反转。晚春初夏的西太平洋副高南撤过程与亚州夏季风爆发、强对流活动和降雨带的移动变化关系密切。在对流层高层西太平洋副高南撤过程的中后期(约4月底),夏季风在安达曼海和临近孟加拉湾爆发。在对流层低层西太平洋副高南撤过程开始后,南海夏季风开始爆发(5月14—15日);南撤过程结束后(6月初),印度夏季风爆发;在副高脊线返回日后(6月中),东亚夏季风爆发。西太平洋副高南撤过程不同阶段的建立时间为预知亚洲不同地区夏季风的爆发时间提供了非常有用的信息。此外,在西太平洋副高主体南北两侧存在两支强的雨带,与副高主体控制的少雨带构成一个典型的"湿干湿"三明治雨型,这个雨型的变化与西太平洋副高脊线移动有关。 相似文献
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Comparison of the multi-scale features in two persistent heavy rainfall events in the middle and lower reaches of Yangtze River 下载免费PDF全文
下载免费PDF全文 Two persistent heavy rainfall(PHR) events in the middle and lower reaches of Yangtze River(MLYR)occurring in June 1982 and 1998 are studied in this paper.Though both events happened in the Meiyu season,their large-scale background and developing processes were quite different.During the PHR event in 1982,the Lake Baikal area was occupied by a strong westerly trough and the western Pacific subtropical high(WPSH) was stronger and more westward-extending than the normal years.Under such a condition,the cold dry air and warm moist air were continuously transported to the MLYR and favored the PHR there.For the event in 1998,the WPSH was similar to that in 1982,while the westerly trough in the Lake Baikal area was comparatively weak and a shortwave trough situating in East China contributed to advect cold dry air to the MLYR.It is found that the high-latitude trough was closely related to the 1030-day low-frequency oscillation while the anomaly of WPSH was linked with the combined effect of both30 60- and 10 30-day low-frequency oscillations in the PHR event in 1982.By contrast,the 60-day low-pass perturbation demonstrated positive impact on the westward extension of WPSH and development of the Baikal trough while the 30 60-day oscillation played a role in strengthening the shortwave trough in East China and the WPSH in the case of 1998.Though the low-latitude 30 60-day oscillations contributed to the intensification and westward extension of the WPSH in both PHR events,their evolution exhibited evident differences.In the 1982 case,the 30 60-day anomalies originated from the western Indian Ocean were much more like the Madden Julian Oscillation,while its counterpart in the 1998 case was much more similar to the first mode of the boreal summer intraseasonal oscillation. 相似文献
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The extremely heavy Meiyu in the middle and lower reaches of the Yangtze River in 2020 features early beginning, extremely late retreat, long duration, and a dramatic north-south swing rain belt. It can be divided into three phases. The key point of the extremely heavy Meiyu is the long duration of precipitation. The physical mechanism of the phased variation is researched here by analyzing the phased evolution of atmospheric circulation, the thermal effect of Tibetan Plateau, the sea surface temperature anomalies (SSTA), and tropical convection. The results show that: (1) Throughout the whole Meiyu season, the western Pacific subtropical high (WPSH) is stronger and westward, the South Asian high (SAH) is stronger and eastward, and blocking highs are very active with different patterns at different stages; they all form flat mid-latitude westerlies with fluctuation interacting with WPSH and SAH, causing their ridges and the rain belt to swing drastically from north to south or vice versa. (2) The higher temperatures in the upper and middle atmosphere in the eastern and southern Tibetan Plateau and the middle and lower reaches of the Yangtze River, which are produced by the warm advection transport, the heat sources in Tibetan Plateau, and the latent heat of condensation of Meiyu, contribute greatly to the stronger and westward WPSH and the stronger and eastward SAH. The dry-cold air brought by the fluctuating westerlies converges with the warm-humid air over Tibetan Plateau, resulting in precipitation, which in turn enhances the heat source of Tibetan Plateau and regulates the swings of WPSH and SAH. (3) Different from climatological analysis, real-time SSTA in the Indian Ocean has no obviously direct effect on WPSH and Meiyu. The anomalous distribution and phased evolution process of real-time SSTA in South China Sea and the tropical western Pacific affect WPSH and Meiyu significantly through tropical convection and heat sources. The maintenance of strong positive SSTA in the western equatorial Pacific is a critical reason for the prolonged Meiyu season. Both the onset and the retreat of Meiyu in 2020 are closely related to the intensified positive SSTA and corresponding typhoons on the ocean east of the Philippines. 相似文献