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1.
太平洋-印度洋海表温度加热对中高纬低频振荡的调频作用 总被引:2,自引:0,他引:2
用数值试验的方法,分别以无热源型、El Nino初期、El Nino成熟期对应的赤道中东太平洋与赤道印度洋海表温度作为外强迫源,应用强迫耗散准地转正压涡度方程的全球谱模式,考虑了摩擦耗散及3波准共振的共同作用,采用非定常、定常加热两种形式积分90d,研究了对中高纬大气低频振荡的调频作用。结果表明:(1)3个行星波之间存在很强的波-波相互作用,且波动振荡呈现准双周和季节内振荡;(2)在El Nino初期和El Nino成熟期,无论是赤道中东太平洋海温还是赤道印度洋海温在逐渐增暖的过程中,大气低频振荡周期都有缩短的趋势。1997年2月-1997年4月,赤道印度洋调节作用强;而在1998年5月,赤道中东太平洋调节作用强;(3)赤道印度洋西区对大气低频振荡的调节作用要强于赤道印度洋东区;Nino3区对大气低频振荡的调节作用要强于Ninol+2区;(4)太平洋-印度洋海温异常模态在1997年10月为高指数(简称PIMI一型),在1996年9月为低指数(简称PIMI二型),前者对应的东太平洋-西印度洋区对大气的调频作用要大于后者对应的西太平洋一东印度洋区。 相似文献
2.
为研究海温的异常增暖对30-60天低频振荡的影响,利用OSU两层大气环流模式作了两组试验:一组使用气候平均海温,另一组包括两个试验,它们分别设正的海温距平(ΔSST)中心位于赤道东太平洋的东部(100°W)和中部(145°W)。结果表明:赤道东太平洋冬半年的海温异常增暖可改变低频振荡方差贡献的地理分布,其中当正的ΔSST中心位于赤道东太平洋的东部时,热带印度洋和西太平洋地区的低频振荡的方差贡献较为显著,而热带东太平洋的低频振荡较为不活跃;当正的ΔSST中心位于赤道东太平洋的中部时,情形则相反,即热带东太平洋的低频振荡的方差贡献较显著,而西太平洋地区的则不活跃。在赤道东太平洋海温异常增暖过程中,低频振荡的传播特性对ΔSST中心位置的响应是敏感的,即当正的ΔSST中心位置偏于该海区的东部或中部时,低频振荡的传播方向和传播速度有明显的差异 相似文献
3.
第一部分(Zhang et al,2001)的资料分析表明,El Nio事件发生之前在赤道中东太平洋存在着显著的异常经向风应力辐合、为了分析这种超前的辐合经向风应力距平在其后的ElNio事件发生中的动力作用,本文利用简单热带海洋动力学模式,从动力学上研究了热带海洋对关于赤道辐合的理想经向风应力强迫的响应,指出赤道东太平洋出现在El Nio事件之前的辐合经向风应力异常有利于El Nio事件的发生。辐合的经向风应力强迫作用于热带海洋,会激发出西传的Rossby波,使得赤道附近的海洋混合层变厚。由于耗散的影响,最大的增厚区位于强迫区域。当这个强迫作用于赤道东太平洋时,这将有利于以 Nl Nio事件发生;另一方面,Rossby波响应在赤道及其附近使得表层海水向西流动,中东太平洋表层水的不断向西输送有利于表层水在西太平洋堆积,为后来暖事件的发生累积能量。 相似文献
4.
本文利用1958~2018年期间海表面温度(SST)异常和湍流热通量异常变化的关系,探讨了其与北太平洋年代际振荡(PDO)相关的年际和年代际时间尺度上在不同海域的海气相互作用特征。结果表明:在年际尺度上,黑潮—亲潮延伸区(KOE)表现为显著大气强迫海洋,赤道中东太平洋表现为显著海洋强迫大气;在年代际尺度上,PDO北中心表现为大气强迫海洋,加利福尼亚附近则表现为显著海洋强迫大气。进一步分析表明:加利福尼亚附近区域是北太平洋准12年振荡的关键区域之一,与PDO准十年的周期类似,加利福尼亚附近的冷(暖)海温对应其上有反气旋(气旋)型环流,赤道中太平洋海水上翻和北太平洋东部副热带区域经向风应力的变化是北太平洋准12年振荡的另外两个重要环节。 相似文献
5.
印度洋-太平洋海温长期变化的周期性及其年代际变化 总被引:12,自引:4,他引:8
运用小波分析方法对近百年来印度洋-太平洋海温的周期变化特征进行了详细讨论,并且结合以前的工作,运用方差分析的方法对近半个世纪以来各周期振荡水平分布的年代际变化进行了综合分析。研究表明:近百年中,赤道东太平洋海温的长期变化不仅具有准两年(QBO)和3-7年(LFO)的年际振荡,而且具有10-12年、18-20年和30-40年的年代际振荡。各振荡分量的振幅和周期具有显著的年代际变化特征。近半个世纪各振 相似文献
6.
7.
第一部分(Zhang et al.,2001)的资料分析表明,El Nino事件发生之前在赤道中东太平洋存在着显著的异常经向风应力辐合.为了分析这种超前的辐合经向风应力距平在其后的ElNino事件发生中的动力作用,本文利用简单热带海洋动力学模式,从动力学上研究了热带海洋对关于赤道辐合的理想经向风应力强迫的响应,指出赤道东太平洋出现在El Nino事件之前的辐合经向风应力异常有利于El Nino事件的发生.辐合的经向风应力强迫作用于热带海洋,会激发出西传的Rossby波,使得赤道附近的海洋混合层变厚.由于耗散的影响,最大的增厚区位于强迫区域.当这个强迫作用于赤道东太平洋时,这将有利于E1 Nino事件发生;另一方面,Rossby波响应在赤道及其附近使得表层海水向西流动,中东太平洋表层水的不断向西输送有利于表层水在西太平洋堆积,为后来暖事件的发生累积能量. 相似文献
8.
用向量场奇异值分解方法分析了赤道太平洋区域风应力场与海表温度场年际异常的相关联系。结果表明,最主要的一对奇异向量与ENSO循环关系密切,其主要特征为赤道中、东太平洋风应力向赤道的异常辐合(辐散)与该区的SST异常升高(降低)准同步变化。对70和80年代的4次 El Ni?o事件中标准化风应力异常场的分析表明,它们均表现出赤道中、东太平洋的辐合。这一结果可能比用信风张弛描述ENSO循环中的环流异常更合理和更具代表性。 相似文献
9.
赤道印度洋海温偶极子型及其气候影响 总被引:13,自引:2,他引:13
对近百年观测资料的分析表明赤道印度洋海温(SST)确实存在着偶极子型振荡的变化特征,它在9-11最强,而在1-4月最弱;年际变化(4-5年周期0和年代际变化(主要为20-25年周期)也十分清楚。这个偶极子主要有正位相型(海温西高东低)和负位相型(海温东高西低);一般正位相型的振幅强于负位相型。尽管在极个别年赤道印度洋海温偶极子似乎与太平洋ENSO无关,但总体而论,赤道印度洋海温偶极子与赤道太平洋海温偶极子(类似ENSO)有很好负相关。它们的联系主要是赤道大气纬向(Walker)环流。资料分析表明,赤道印度洋海温偶极子与亚洲南部流场、青藏高原和西太平洋副高都有明显关系,表明它对亚洲季风活动有重要影响。 相似文献
10.
利用NCEP/NCAR逐日风场及英国气象局逐月海表温度资料,研究了对流层高低层风场季内振荡强度季节变化特征,探讨了其年际及年代际异常特征与海表温度异常的关系。热带印度洋、热带西太平洋是高低层风场季内振荡终年均活跃的区域。对流层高低层风场季内振荡强度异常与海表温度异常均不存在确定的局地关系。风场季内振荡能量异常与海表温度异常在年代际尺度上具有良好对应关系,20世纪70年代中后期以来,赤道东太平洋海温异常升高,Walker环流减弱,导致亚洲区域季风季内振荡强度减弱,赤道太平洋区域200hPa(850hPa)风场季内振荡在赤道东太平洋增强(减弱),在印度洋东南部—印尼—中西太平洋的暖池区域减弱(增强),促进了ElNino事件的增强。对流层高低层风场季内振荡强度年际异常与ElNino事件关系密切,这一特征在低层(850hPa)风场表现更显著。在事件发展初期,热带中西太平洋区域850hPa风场季内振荡异常增强并东移,事件发生之后这些区域能量减弱。大气季内振荡可能是ElNino事件的激发因素。 相似文献
11.
INTERANNUAL LOW-FREQUENCY OSCILLATIONS OF MERIDIONAL WINDS OVER THE EQUATORIAL INDIAN-PACIFIC OCEANS 
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下载免费PDF全文 Based on analysis of the meridional winds over oceanic areas and SST for 1950-1979 extracted from the data sets of COADS, the long-term variability of the meridional winds over the equatorial Indian-Pacific oceans and its relationship to the onset and development of El Nino events have been studied. The major results are as follows:(1) There is a great similarity between ITCZ over the Pacific and SST in the seasonal trend, with ITCZ and high SST found in the Southern Hemisphere in winter and in the Northern Hemisphere in summer.During El Nino years, unusual meridional winds were often observed, with significant convergence of meridional winds occurring over near-equatorial regions.(2) For the near-equatorial meridional winds, there are three types of interannual LFO:QBO, SO, FYO. QBO plays an important role in the unusual behavior of meridional winds for El Nino years, while SO is very important for both El Nino and cold water years. These two oscillations may fit well to the observed variation in the meridional wind. FYO may enhance the variation of meridional winds.(3) Interannual LFO of meridional winds originates in the Indian Ocean-Maritime Continent and coastal area of East Pacific. Unusual activities of winter monsoon in both hemispheres and trade winds off the coastal area of East Pacific are believed to be their major cause.(4) Monsoon-trade interaction shows up in the significant amplification of the disturbances of meridional winds while they propagate eastward from monsoon area to trade wind area. 相似文献
12.
The time series of sea surface temperature (SST), sea level pressure (SLP), zonal wind (U) and total cloudiness (CA), for the period of 1950-1979, over a 8o×8o grid-point latitudinal belt between 32oS and 32oN are made from COADS (Comprehensive Ocean-Atmosphere Data Set). The time harmonic analysis and power spectra analysis show that there exist quasi-biennial oscillation (QBO), three and half years oscillation (SO), five and half years oscillation (FYO) and eleven years oscillation (EYO) in these time series. The main propagation characteristics of these interannual low-frequency oscillations are as follows:(1) The variance analysis of SST shows that there is an active region of QBO and SO (with maximum variance), coming from the southwestern part of the subtropical Pacific, stretching eastward up to the west coast of South America, and then northward to the eastern equatorial Pacific. The QBO and SO disturbances of SST follow the same route and cause the anomaly of SST (El Nino and period of cold water) in the eastern equatorial Pacific.(2) Either the QBO or SO of SST can cause El Nino events, although it is easier when they are situated in the same phase of warm water at the eastern equatorial Pacific. The FYO of SST seems to be a standing oscillation. It plays an important role on the formation of strong El Nino events or strong cold water events.(3) The QBO and SO of U propagate eastward along the equator. The origin of QBO and SO may at least be traced as far as the western Indian Ocean. While they propagate along the equator, it strengthens two times at 90oE and the western Pacific, respectively. Like SST, the FYO of U is somehow a standing oscillation.(4) The Oscillations of U have a good coupling relationship with those of SST, while they propagate. When the QBO and SO of SST move to the east side of the eastern equatorial Pacific, it is the time for the QBO and SO of U to enter into the east part of the western Pacific.It is clear that, when we do research work on the formation of El Nino events, our consideration would not be confined to the tropics, it should cover the subtropical region in the southern Pacific. The features of the circulation and other oceanic states in this area are very important to the El Nino events. 相似文献
13.
A simplified data set with 8°×8° grid system in a region of 32°S-32°N from 1951 to 1979 for the elements of sea surface temperature (SST),zonal wind at sea level (U),sea level pressure (SLP) and total cloud amount (CA) is made from the COADS.The oscillation components with periods of 2 years (QBO),3.5 years (SO) and 5.5 years (FYO) in interannual low-frequency oscillations have been studied by using the methods of extended EOF (EEOF) and lag comelation analysis with the oscillational components of SST in the equator of eastern Pacific as the reference element.In our paper,the relationship between oscillation components and occumence of El Nino is also investigated. 相似文献
14.
The characteristics of 30-60 day oscillation (hereafter called LFO ) of the outgoing longwave radiation data (OLR) and its relations to the interannual oscillations of the sea surface temperature (SST) are investigated by using the daily OLR data for the period from January, 1979 to December, 1987 and the corresponding monthly SST data. II is found that the LFO the band the interannual oscillations of the SST monthly anomaly (SSTA) interact each oth-er and they all relate to the occurrence and development of El Nino events closely. Before El Nino event happens, it contributes to the SST’s warming up and to the SST’s quasi-biennial oscillation (called QBO for brevity) and three and half years oscillation (called SO for short) being in warm water phase in the equatorial central and eastern Pacific (ECP and EEP) that the LFO in the equatorial western Pacific (EWP) enhances and propagates eastward; When El Nino event takes place, the LFO, SSTA and SSTA’s QBO and SO in the EEP interact and strengthen each other; But the warmer SST and the SSTA’s QBO and SO in the warm water phase in the EEP contribute to the LFO's weak-ening in the equatorial Pacific. Moreover, these contribute to the SST in the EEP becoming cold and the SSTA’s QBO and SO in the EWP being in cold water phase and then impel the El Nino event to end. 相似文献
15.
Asian summer monsoon prediction in ECMWF System 4 and NCEP CFSv2 retrospective seasonal forecasts 总被引:3,自引:1,他引:2
The seasonal prediction skill of the Asian summer monsoon is assessed using retrospective predictions (1982–2009) from the ECMWF System 4 (SYS4) and NCEP CFS version 2 (CFSv2) seasonal prediction systems. In both SYS4 and CFSv2, a cold bias of sea-surface temperature (SST) is found over the equatorial Pacific, North Atlantic, Indian Oceans and over a broad region in the Southern Hemisphere relative to observations. In contrast, a warm bias is found over the northern part of North Pacific and North Atlantic. Excessive precipitation is found along the ITCZ, equatorial Atlantic, equatorial Indian Ocean and the maritime continent. The southwest monsoon flow and the Somali Jet are stronger in SYS4, while the south-easterly trade winds over the tropical Indian Ocean, the Somali Jet and the subtropical northwestern Pacific high are weaker in CFSv2 relative to the reanalysis. In both systems, the prediction of SST, precipitation and low-level zonal wind has greatest skill in the tropical belt, especially over the central and eastern Pacific where the influence of El Nino-Southern Oscillation (ENSO) is dominant. Both modeling systems capture the global monsoon and the large-scale monsoon wind variability well, while at the same time performing poorly in simulating monsoon precipitation. The Asian monsoon prediction skill increases with the ENSO amplitude, although the models simulate an overly strong impact of ENSO on the monsoon. Overall, the monsoon predictive skill is lower than the ENSO skill in both modeling systems but both systems show greater predictive skill compared to persistence. 相似文献
16.
通过分析下半年Nino3区(150o~90oW,5oS~5oN)海表温度(SST)升高引起的次年春季500 hPa高度、850 hPa及200 hPa经向风的异常特征,发现下半年Nino3区显著升温,可导致次年春季热带和西北太平洋副热带地区的500 hPa高度场升高,即西太平洋副热带高压偏强、偏西、偏北,东亚大槽偏弱、偏东;巴尔喀什湖至贝加尔湖的高度场降低,即该地区经常有低槽维持;亚洲至西太平洋地区盛行纬向环流。我国东部沿海地区及邻近海域的偏南风加强,而我国东北和华北地区的偏北风偏弱。这种高度场与风场的异常恰与山东4月降水偏多年所对应的异常特征相吻合,即下半年Nino3区显著升温通过影响次年春季大气环流异常,进而影响山东春季降水。资料统计表明,下半年Nino3区显著升温,次年山东及我国中纬度东部地区春季尤其4月的降水往往偏多。 相似文献
17.
利用MPAS-A(The Model for Prediction Across Scales-Atmosphere)模式设计了中东太平洋热带辐合带CEP-ITCZ(Intertropical Convergence Zone over Central and Eastern Pacific)对两类厄尔尼诺SST(Sea Surface Temperature)异常的敏感性试验,通过试验结果与两类厄尔尼诺年实际大气异常的对比,初步解释了CEP-ITCZ在两类厄尔尼诺年产生不同异常的可能原因。通过CP-EL试验发现,热带太平洋SST异常的第一模态会使中东太平洋低层风场辐合增强,但对辐合带的位置影响不大,与中部型厄尔尼诺对CEP-ITCZ的影响基本一致。通过EP-EL试验发现,热带太平洋SST异常的第二模态会使中东太平洋低层风场产生较大异常,辐合带中心向南移动,辐合带明显减弱增宽,与东部型厄尔尼诺对CEP-ITCZ的影响基本一致。 相似文献
18.
Soon-Il An 《Theoretical and Applied Climatology》2004,78(4):203-215
Summary The interannual variability of sea surface temperature (SST) anomalies in the tropical Indian Ocean is dominated mainly by a basin-scale mode (BM) and partly by an east–west contrast mode (zonal mode, ZM). The BM reflects the basin-scale warming or cooling and is highly correlated with El Nino with 3- to 6-month lags, while the ZM is marginally correlated with El Nino with 9-month lags.During an El Nino, large-scale anomalous subsidence over the maritime continent occurs as a result of an eastward shift in the rising branch of the Walker circulation suppresses convection over the eastern Indian Ocean, allowing more solar radiation over the eastern Indian Ocean. At the same time, the anomalous southeasterly wind over the equatorial Indian Ocean forces the thermocline over the western Indian Ocean to deepen, especially in the southern part. As a result, SST over the whole basin increases. As El Nino decays, the subsidence over the maritime continent ceases and so does the anomalous southeasterly wind. However, the thermocline perturbation does not quickly shoal back to normal because of inertia and it disperses as Rossby waves. These Rossby waves are reflected back as an equatorial Kelvin wave, causing deepening of the thermocline in the eastern Indian Ocean, and preventing SSTs from cooling in that region. Moreover, the weaker wind speed of the monsoon circulation results in less latent heat loss, and thus warms the eastern Indian Ocean. These two processes therefore help to maintain warm SSTs over the eastern Indian Ocean until fall. During the fall, the warm SST over the eastern Indian Ocean and the cold SST over the western Indian Ocean are enhanced by air–sea interaction and the ZM returns. The ZM dissipates through the seasonal reversal of the monsoon atmospheric circulation and the boundary-reflected Kelvin wave. In the same manner, a basin-scale cooling in the tropical Indian Ocean can induce the ZM warming in the west and cooling in the east. 相似文献
19.
运用小波分析方法和相关分析对东亚季的准两年振荡的存在及其与ENSO变率的关系进行了研究,结果指出:东亚季风具有显著的准两年振荡特征,但周期与振幅具有明显的年代际变化,同时东亚季风的QBO过程与ElNino事件具有密切的联系; 相似文献
20.
Pascal Terray 《Climate Dynamics》2011,36(11-12):2171-2199
The main goal of this paper is to shed additional light on the reciprocal dynamical linkages between mid-latitude Southern Hemisphere climate and the El Ni?o-Southern Oscillation (ENSO) signal. While our analysis confirms that ENSO is a dominant source of interannual variability in the Southern Hemisphere, it is also suggested here that subtropical dipole variability in both the Southern Indian and Atlantic Oceans triggered by Southern Hemisphere mid-latitude variability may also provide a controlling influence on ENSO in the equatorial Pacific. This subtropical forcing operates through various coupled air?Csea feedbacks involving the propagation of subtropical sea surface temperature (SST) anomalies into the deep tropics of the Atlantic and Indian Oceans from boreal winter to boreal spring and a subsequent dynamical atmospheric response to these SST anomalies linking the three tropical basins at the beginning of the boreal spring. This atmospheric response is characterized by a significant weakening of the equatorial Atlantic and Indian Inter-Tropical Convergence Zone (ITCZ). This weakened ITCZ forces an equatorial ??cold Kelvin wave?? response in the middle to upper troposphere that extends eastward from the heat sink regions into the western Pacific. By modulating the vertical temperature gradient and the stability of the atmosphere over the equatorial western Pacific Ocean, this Kelvin wave response promotes persistent zonal wind and convective anomalies over the western equatorial Pacific, which may trigger El Ni?o onset at the end of the boreal winter. These different processes explain why South Atlantic and Indian subtropical dipole time series indices are highly significant precursors of the Ni?o34 SST index several months in advance before the El Ni?o onset in the equatorial Pacific. This study illustrates that the atmospheric internal variability in the mid-latitudes of the Southern Hemisphere may significantly influence ENSO variability. However, this surprising relationship is observed only during recent decades, after the so-called 1976/1977 climate regime shift, suggesting a possible linkage with global warming or decadal fluctuations of the climate system. 相似文献