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1.
影响山东热带气旋的频数与太平洋海温的关系 总被引:1,自引:0,他引:1
利用1949—2007年热带气旋年鉴资料,对影响山东热带气旋(TC)的频数与太平洋海温的关系进行了分析。结果表明:(1)厄尔尼诺年,影响山东的TC频数较常年明显偏少。厄尔尼诺次年TC频数较常年稍有增加。拉尼娜年影响山东的TC频数较常年显著偏多,增加明显的月份主要是8月和9月,拉尼娜次年,影响山东TC频数偏少。厄尔尼诺事件强度越大,影响山东的TC频数越少。(2)影响山东的TC数和菲律宾以东洋面的海温呈正相关,并具有很好的持续性。(3)影响山东的TC多年,赤道中东太平洋有较强的负距平区;影响山东的TC少年,赤道中东太平洋为正距平区。说明赤道中东太平洋的海温高低对影响山东的TC频数有较好的指示作用。 相似文献
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南海和西北太平洋热带气旋活动的区域性差异分析 总被引:4,自引:2,他引:2
利用近58年(1950~2007年)热带气旋资料,研究了南海(5°N~25°N,110°E~120°E)和西北太平洋(5°N~25°N,120°E~180°)两个区域热带气旋生成频数的年际变化和季节变化特征,结果表明西北太平洋热带气旋生成频数明显多于南海,且两区域的热带气旋活动表现出明显的区域性差异。在年际变化上,两者之间相关系数仅为-0.09,即南海和西北太平洋热带气旋生成频数在变化上相对独立。在季节变化上,西北太平洋热带气旋生成频数主要决定了整个西北太平洋明显的季节变化特征,而南海热带气旋生成频数在活跃期5~11月内季节差异不够明显,8~9月为相对盛期;特别地,从热带气旋频数相对于整个西北太平洋所占比率来看,5~6月南海区域由前期的寂静期骤然上升至31.7%~33.8%,使得5~6月成为全年比率中最突出的2个月份。对上述热带气旋活动区域性差异的可能原因进行了分析,初步显示在年际变化上ENSO对南海热带气旋生成频数的影响是显著的;在季节变化上,5~6月南海出现了较之西北太平洋更加有利于热带气旋生成的动力条件(季风槽)和热力条件(高海温),这可能是南海热带气旋生成频数相对于整个西北太平洋所占比率在5~6月成为全年最突出的两个月份的主要原因。 相似文献
3.
近58年来登陆中国热带气旋气候变化特征 总被引:12,自引:1,他引:11
利用1949-2006年<台风年鉴>和<热带气旋年鉴>资料,主要分析了1949-2006年登陆中国热带气旋的频数、登陆位置、登陆季节延续期和登陆强度等要素及其概率分布的年际和年代际变化特征.结果表明:近58年来,登陆中国热带气旋年频数有减少趋势,但登陆时达台风强度的年频数变化不明显;按登陆地点分区统计发现,登陆华南地区的热带低压及(强)热带风暴年频数以减少为主,而登陆东部地区的热带气旋年频数变化不明显.登陆点历年最北位置(最南位置)有南移(弱的北移)趋势,导致登陆点历年南北最大纬度差逐渐减小,这表明热带气旋登陆区域更为集中,在23°-35°N增多,而在35°N以北和23°N以南以减少为主.登陆中国热带气旋季节延续期缩短了近1个月.热带气旋年平均登陆强度及其概率分布偏度有增加趋势,表明登陆的强台风有增加;登陆中国华南和东部地区的台风强度都有增强趋势,前者比后者趋势更明显.另外,热带气旋年最大登陆强度差长期呈现减小的趋势. 相似文献
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5.
利用欧洲中期天气预报中心的ERA-Interim再分析资料驱动CWRF模式对1982-2016年中国近海的热带气旋活动进行了模拟,分析了CWRF对热带气旋频数季节、年际变化和路径的模拟能力,并探讨了环境场模拟对热带气旋模拟的影响。结果表明:CWRF能够合理模拟热带气旋频数的季节和年际变化,但模拟的频数较观测总体偏低,季节变化模拟总体优于年际变化的模拟;模式基本上能模拟出热带气旋路径密度的空间分布,但CWRF明显总体低估了气旋路径密度。进一步分析发现,模式模拟的环境场对模拟结果具有十分重要的影响。850 hPa气旋性与反气旋性环流异常对热带气旋频数影响显著;200 hPa反气旋性环流异常与东亚西风急流对热带气旋路径影响较大;副高会影响洋面对流运动从而影响热带气旋频数,其南侧偏东风则会影响热带气旋路径;垂直风切变偏小,在不同纬度对热带气旋的影响是不同的。 相似文献
6.
西北太平洋与南海热带气旋活动季节变化的差异及可能原因 总被引:1,自引:0,他引:1
利用1945~2011年美国联合台风预警中心(JTWC)西北太平洋热带气旋资料,研究了南海(5°N~25°N,110°E~120°E)与西北太平洋(5°N~25°N,120°E~180°)热带气旋生成位置、生成频数、强度和持续时间的季节变化差异及其成因。从热带气旋路径穿越经度带频数的角度,探讨了ENSO对气旋活动年际变化的影响。结果表明,南海热带气旋活动显著地受季风调控。在南海冬季风作用下,1~4月热带气旋生成于10°N以南且频数较少、强度较弱,这主要是低层气旋式相对涡度和弱东风切变区偏南造成的。相反,受夏季风影响,6~9月是热带气旋生成最多、最频繁的季节,大都生成于南海北部17°N附近。在5月(10月)的季节转换期,生成位置大幅度北进(南撤)且生成频数显著增加(减少),取决于风速垂直切变及中层的相对湿度的急剧转变。11、12月两海域热带气旋生成于10°N以南主要归因于其上空中层大气相对湿度较北部偏大。在西北太平洋,热带气旋生成的季节变化没有南海显著,只在7月有一次明显的变化,7~10月是热带气旋活动的"盛期"。在强度上,西北太平洋大部分区域全年均为弱东风切变,因此热带气旋以台风为主且持续时间长;但南海多为热带风暴。ENSO事件使得不同季节热带气旋生成区域和气旋路径地理位置发生显著变化。在El Nio事件期间,穿越南海所在经度带路径频数为负距平,而西北太平洋经度带为正距平;在La Nia事件期间,情况相反。 相似文献
7.
气候变化背景下我国周边海域热带气旋灾害风险评估与区划 总被引:7,自引:4,他引:3
针对气候变化背景下热带气旋的演变趋势与灾害风险,探讨了我国周边海域热带气旋强度及频数的气候变化特征,从风险分析的角度提出了热带气旋灾害风险概念框架,基于风险评价指数法初步构建了风险评估的指标体系和数学模型,应用GIS技术实现了我国周边海域热带气旋灾害风险的等级区划。结果显示,在气候变化背景下,我国周边海域热带气旋频数和平均强度在近60年来呈现弱的下降趋势,但近10年来,台风及以上级别热带气旋频数和强度极值明显增加;热带气旋灾害高风险区位于南海北部和菲律宾海东部洋面。 相似文献
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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
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
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利用1949—2003年近55 a的西北太平洋热带气旋(WNPTC)移动路径6 h中心经纬度矢量资料,矢量栅格化到1°×1°网格,统计WNPTC出现的次数、不同移动方向的次数及走向率,结果表明:(1)西北太平洋热带气旋空间分布具有积聚性,从生成源区向外递减。WNPTC消亡区在陆地比较集中,而洋面上相对离散;(2)WNPTC季节变化明显,冬季大值中心纬度最低,春季次之,夏季达到最高,秋季较夏季向南偏移1~3个纬度;(3)在El Nino次年热带气旋增多的区域,而La Nina次年热带气旋减少,15°N附近为分界线,反之亦然;(4)西北太平洋热带气旋移动方向和走向率除具有明显的纬向分布特点,在经向方向上也有差异;各个移动方向区域与其相对应的走向率区域基本相同,但是最大值中心并不重合。 相似文献
11.
Spatial and Temporal Variations of Tropical Cyclones at Different Intensity Scales over the Western North Pacific from 1945 to 2005 
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下载免费PDF全文 The tropical cyclone (TC) track data provided by the Joint Typhoon Warning Center (JTWC) of the U.S. Navy over the western North Pacific (including the South China Sea) from 1945 to 2005 are employed to analyze the temporal and spatial variations of TCs of different intensity scales. Most of the TCs occurred between 15° and 25°N, from the northern part of the South China Sea to the eastern part of the Bashi Channel until near 140°E. Most of the severe and super typhoons occurred over waters from the eastern part of the Bashi Channel to about 140°E. The TCs in a weakening or steady state take up a weak majority in the area west of 123°E and north of 20°N; those in an intensifying or steady state are mostly found in the area east of 123°E and south of 20°N. For severe tropical storms, typhoons, severe typhoons, and super typhoons, their average decaying rates are all greater than the respective average growing rates; for tropical storms, however, the average decaying rate is smaller than the average growing rate. Generally speaking, the stronger the TC, the faster the intensification (weakening) is. The percentage of weak TCs is higher in June to August while that of strong TCs is higher in September to November. There are annual, interannual, and interdecadal variations in the observed number (every 6 h) and frequency of TCs at different intensity scales. As far as the long-term trend is concerned, the frequency and observed number of tropical storms have a significant linear increase, but the averaged intensity and number of TCs of other intensity categories do not exhibit such a significant linear trend. In E1 Nifio years, the number and percentage of super typhoons are significantly higher, while the total number of tropical storms, severe tropical storms, typhoons, and severe typhoons is significantly lower, and the mean intensity of TCs is prominently stronger; in La Nifia years, however, the opposite comes true. 相似文献
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We used tropical cyclone (TC) best track data for 1949–2016, provided by the Shanghai Typhoon Institute, China Meteorological Administration (CMA-STI), and a TC size dataset (1980-2016) derived from geostationary satellite infrared images to analyze the statistical characteristics of autumn TCs over the western North Pacific (WNP). We investigated TC genesis frequency, location, track density, intensity, outer size, and landfalling features, as well as their temporal and spatial evolution characteristics. On average, the number of autumn TCs accounted for 42.1% of the annual total, slightly less than that of summer TCs (42.7%). However, TCs classified as strong typhoons or super typhoons were more frequent in autumn than in summer. In most years of the 68-yr study period, there was an inverse relationship between the number of autumn TCs and that of summer TCs. The genesis of autumn TCs was concentrated at three centers over the WNP: the first is located near (14°N, 115°E) over the northeastern South China Sea and the other two are located in the vast oceanic area east of the Philippines around (14°N, 135°E) and (14°N, 145°E), respectively. In terms of intensity, the eight strongest TCs during the study period all occurred in autumn. It is revealed that autumn TCs were featured with strong typhoons and super typhoons, with the latter accounting for 28.1% of the total number of autumn TCs. Statistically, the average 34-knot radius (R34) of autumn TCs increased with TC intensity. From 1949 to 2016, 164 autumn TCs made landfall in China, with an average annual number of 2.4. Autumn TCs were most likely to make landfall in Guangdong Province, followed by Hainan Province and Taiwan Island.
相似文献13.
The present study revealed that a climate regime shift occurred during the 1988–1991 period involving changes in tropical cyclone (TC) intensity (central pressure, maximum sustained wind speed) during the summer near 30°N in East Asia. Climatologically, TC intensity at 110°–125°E near 30°N (over Mainland China) is the weakest at that latitude while the strongest is found at 125°–130°E (over Korea). The TC intensity during the 1991–2015 (91–15) period had strengthened significantly compared to that of the 1965–1988 (65–88) period. The strengthening was due to a significantly lower frequency of TCs that passed through Mainland China during the 91–15 period. This lower frequency of was due to anomalous northeasterlies blown from the anomalous anticyclonic circulation located over continental East Asia and that had strengthened along the coast. Instead, TCs mainly followed a path from eastern regions in the subtropical western North Pacific to Korea and Japan via the East China Sea due to anomalous cyclonic circulations that had strengthened in the western North Pacific. In addition, low vertical wind shear had formed along the mid-latitude region in East Asia and along the main TC track in the 91–15 period, and most regions in the western North Pacific experienced a higher sea surface temperature state during the 91–15 period than in the previous period, indicating that a favorable environment had formed to maintain strong intensities of TCs at the mid–latitudes. The characteristics of TCs at the lower latitudes caused a strong TC intensity at the time of landfall in Korea and a gradual shifting trend of landing location from the western to southern coast in recent years. 相似文献
14.
应用NOAA气候预测中心提供的热带大气季节内振荡(MJO)客观业务指数及中国气象局上海台风研究所提供的西北太平洋热带气旋(TC)最佳路径资料集,定量统计榆验了MJO对夏季西北太平洋TC活动的调制作用.结果表明:MJO对TC的生成、强度、路径和登陆活动都有显著的调节作用.当高空辐合中心位于120°E~160°E(MJO位相3~5)时,西北太平洋TC生成偏少,且生成位置偏北;而当高空辐合中心位于10°W~70°E(MJO位相8~10)时,西北太平洋TC生成偏多,且生成位置偏南;随着TC强度加强,能达到显著调节作用的MJO位相逐渐减少,当高空辐合辐散中心位于70°E(MJO位相10)时,对TC强度调制最显著.在路径调节方面,MJO位相1~4和10时,TC活跃于菲律宾以东的西北太平洋上,主要路径为西北偏北行,可能登陆华东、华北;而位相5~8时,TC主要活跃在菲律宾附近及以西到南海,以偏西行路径为主,可能登陆华南.MJO对登陆华南TC也有显著影响.该定量统计检验结果可为TC活动季节内预测提供依据. 相似文献
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The intraseasonal oscillation(ISO) of the South China Sea(SCS, 105-120°E, 5-20°N) convection and its influences on the genesis and track of the western North Pacific(WNP) tropical cyclones(TCs) were explored, based on the daily average of NCEP/NCAR reanalysis data, the OLR data and the western North Pacific tropical cyclone best-track data from 1979 to 2008. The mechanism of the influences of ISO on TC movement and the corresponding large-scale circulation were discussed by a trajectory model. It was found as follows.(1) During the SCS summer monsoon, the SCS convection exhibits the ISO features with active phases alternating with inactive phases. The monsoon circulation patterns are significantly different during these two phases. When the SCS convection is active(inactive), the SCS-WNP monsoon trough stretches eastward(retreats westward) due to the activity(inactivity) of SCS monsoon, and the WNP subtropical high retreats eastward(stretches westward), which enhances(suppresses) the monsoon circulation.(2) The amount of TC genesis in the active phase is much more than that in the inactive phase. A majority of TCs form west of 135 °E during the active phases but east of 135 °E in the inactive phases.(3) The TCs entering the area west of 135 °E and south of 25 °N would move straight into the SCS in the active phase, or recurve northward in the inactive phase.(4) Simulation results show that the steering flow associated with the active(inactive)phases is in favor of straight-moving(recurving) TCs. Meanwhile, the impacts of the locations of TC genesis on the characteristics of TC track cannot be ignored. TCs that occurred father westward are more likely to move straight into the SCS region. 相似文献
16.
西北太平洋热带气旋强度变化的统计特征 总被引:14,自引:9,他引:14
用中国气象局整编的1949-2003年共55年的《台风年鉴》和《热带气旋年鉴》资料,依据平均值与标准差的数学涵义,给出了TC突然增强、缓慢增强、强度稳定、缓慢减弱和突然减弱的标准,分析了西北太平洋热带气旋(TC)强度变化的年代际、年际、月际、日变化和区域分布的基本特征。结果表明:(1)1960年代以前,T℃的年平均增强或减弱幅度较小。(2)在TC出现较为频繁的夏秋季节,8月份TC强度变幅较小。TC在14时(北京时,下同)最易发展,20时最易减弱;08时TC增强速度最快,02时最慢;02时TC减弱速度最快, 20时最慢。(3)TC频数和增强TC频数的高值区位于海南岛以东的南海北部中国近海区域和菲律宾以东洋面,减弱类TC频数极值区在吕宋岛及其东部海域、海南岛以西的北部湾、广东沿岸。(4)TC突然增强不出现在30°N以北的中高纬地区和0—5°N的低纬地区。TC突然减弱多出现在125°E以西的中国近海大范围海域,在0~5°N的低纬地区基本不出现。 相似文献
17.
影响我国热带气旋活动的气候特征及其与太平洋海温的关系 总被引:23,自引:14,他引:23
利用1956~2000年的热带气旋(简称TC,下同)资料对影响我国TC活动的气候特征进行了初步的统计分析,结果发现影响我国的TC活动具有明显的阶段性特征,1960年代影响我国的TC数明显偏少,而后进入偏多期,1990年代又相对偏少。影响我国的TC强度多集中于980~999 hPa,华东的闽、浙一带TC登陆比华南晚,但强度较大。在此基础上通过对影响我国的TC年个数与太平洋海温场进行相关分析,发现两个相关较密切的区域: 西太平洋暖池(120~150 E, 10~20 N)正相关区、赤道中东太平洋(180 ~90 W, 10 S~5 N)负相关区,这两个相关区具有较好的持续性。进一步分析影响我国的TC在El Ni駉年与La Ni馻年的气候特征发现,El Ni駉年影响我国的TC数较少,但强度较大,La Ni馻年则相反,影响我国TC多年和少年对应的太平洋海温距平分布形势分别与La Nia年和El Nio年的海温距平分布形势类似。 相似文献
18.
Soon-Chang Yoon Sang-Woo Kim Suk-Jin Choi In-Jin Choi 《Asia-Pacific Journal of Atmospheric Sciences》2010,46(3):279-286
We investigated the regional-scale relationships between columnar aerosol loads and summer monsoon circulation, and also the precipitation over northeast Asia using aerosol optical depth (AOD) data obtained from the 8-year MODIS, AERONET Sun/sky radiometer, and precipitation data acquired under the Global Precipitation Climatology Project (GPCP). These high-quality data revealed the regional-scale link between AOD and summer monsoon circulation, precipitation in July over northeast Asian countries, and their distinct spatial and annual variabilities. Compared to the mean AOD for the entire period of 2001–2008, the increase of almost 40–50% in the AOD value in July 2005 and July 2007 was found over the downwind regions of China (Yellow Sea, Korean peninsula, and East Sea), with negative precipitation anomalies. This can be attributable to the strong westerly confluent flows, between cyclone flows by continental thermal low centered over the northern China and anticyclonic flows by the western North Pacific High, which transport anthropogenic pollution aerosols emitted from east China to aforementioned downwind high AOD regions along the rim of the Pacific marine airmass. In July 2002, however, the easterly flows transported anthropogenic aerosols from east China to the southwestern part of China in July 2002. As a result, the AOD off the coast of China was dramatically reduced in spite of decreasing rainfall. From the calculation of the cross-correlation coefficient between MODIS-derived AOD anomalies and GPCP precipitation anomalies in July over the period 2001–2008, we found negative correlations over the areas encompassed by 105–115°E and 30–35°N and by 120–140°E and 35–40°N (Yellow Sea, Korean peninsula, and East Sea). This suggests that aerosol loads over these regions are easily influenced by the Asian monsoon flow system and associated precipitation. 相似文献
19.
南海至西太平洋一带夏季低空越赤道气流和季风的初步研究 总被引:4,自引:3,他引:4
本文对南海至西太平洋一带夏季低空越赤道气流的情况和西南季风的来源,进行了初步研究。发现:(1)就气候平均而言,东非低空急流的影响范围,包括印度南部、孟加拉湾南部直到中南半岛南部和南海南部。在这一范围内,夏季月平均西南季风强度的年际变化十分一致;(2)夏季在中南半岛南部、南海南部,西南季风的主要来源是上游印度、孟加拉湾地区,直接来自南半球的气流比重不大。而热带西北太平洋的西南季风,则主要来自南半球;(3)在110-140°E 的赤道地区,并不存在一支主要的越赤道气流;(4)在150°E 附近的新几内亚东岸,有一条越赤道气流的通道。热带西北太平洋的西南季风,主要就是这支越赤道气流转向而成(但似乎要求这支气流的南风分量强度超过某一下限,即存在一阈值,才能对西北太平洋的西南季风变化有影响)。新几内亚岛上的山脉,对南半球东南信风的阻挡,是形成这支越赤道气流的重要原因之一;(5)大致在15°N 以南的南亚至西北太平洋地区,其西南季风主要由二支气流构成:一支在非洲东岸附近越过赤道,成为东非低空急流,经印度南部,往下游一直影响到南海南部;另一支在新几内亚东岸附近越过赤道,转向成西南气流影响西北太平洋。 相似文献