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1.
通过一个全球的二维诊断模型,采用Levitus温盐资料和COADS风应力资料,并结合动力计算来研究南海上层环流的季节变化。计算结果与其它模式结果和观测结果非常相似。南海北部(南部)全年存在一气旋式(反气旋式)环流。在冬季气旋式环流几乎占据了整个南海,夏季则以反气旋式环流为主。泰国湾的环流在冬季(夏季)是气旋式的(反气旋的)。南海的西边界流有明显的季节变化,其在冬季从卡里马塔海峡流出南海,夏季部分西边界流从台湾海峡流出南海。越南离岸流在春季就开始出现,其位置比夏季的越南离岸流的位置偏北。 相似文献
2.
《海洋与湖沼》2012,43(2)
基于CORA再分析资料对南海环流的季节特征和其受ElNino事件的响应进行了分析。结果表明,冬季整个南海海区表现为一个大的气旋式环流,夏季南海北部是气旋式环流,南部是一个反气旋式环流。通过对南海海区异常流场进行MV-EOF分解,分析其前两个模态,其空间型主要体现了南海环流冬季和夏季的特征,对应的时间系数与ElNino3.4_4NDJ指数有很好的相关性。通过分析南海环流在1986--2008年间ElNino年份的异常流场和异常流函数场,证明了MV-EOF分解后得到的联合时间系数所反映各阶段南海环流的季节特征与ElNino事件有相关性,即在8月[0],南海南部异常流函数场表现为反气旋式环流,北部为气旋式环流,南海夏季环流被增强,且ElNino事件时间尺度越长,北部的气旋式异常流场的影响范围就越大;在12月[0],南海除了东南部外,其余整个海区异常流函数场主要表现为反气旋式环流,冬季环流被减弱;在8月[+1],南海夏季流场强度都被削弱了。 相似文献
3.
基于CORA再分析资料对南海环流的季节特征和其受ElNio事件的响应进行了分析。结果表明,冬季整个南海海区表现为一个大的气旋式环流,夏季南海北部是气旋式环流,南部是一个反气旋式环流。通过对南海海区异常流场进行MV-EOF分解,分析其前两个模态,其空间型主要体现了南海环流冬季和夏季的特征,对应的时间系数与Nio3.4_NDJ指数有很好的相关性。通过分析南海环流在1986—2008年间ElNio年份的异常流场和异常流函数场,证明了MV-EOF分解后得到的联合时间系数所反映各阶段南海环流的季节特征与ElNio事件有相关性,即在8月[0],南海南部异常流函数场表现为反气旋式环流,北部为气旋式环流,南海夏季环流被增强,且ElNio事件时间尺度越长,北部的气旋式异常流场的影响范围就越大;在12月[0],南海除了东南部外,其余整个海区异常流函数场主要表现为反气旋式环流,冬季环流被减弱;在8月[+1],南海夏季流场强度都被削弱了。 相似文献
4.
利用WAVEWATCHⅢ海浪模式模拟的1993-2011年中国东部海域19 a冬季逐日海浪场资料以及同期CCMP逐日风场资料,采用奇异值分解(SVD)的方法分析了冬季中国东部海域海浪场与提前0~5 d的东亚大陆地面风场的关联特征。结果发现:海浪场与提前1 d的地面风场的关联更有意义;SVD第一模态和第二模态分别反映了贝加尔湖以东南下的反气旋式偏北扰动大风(或气旋式偏南扰动大风)和中国东部平原入海的气旋式扰动风场(或反气旋式扰动风场)对中国东部海域海浪的扰动影响。此外,SVD分析还揭示了冬季影响中国东部海域海浪的大风关键区和移动路径;随着时间的推移,大风关键区从贝加尔湖以东逐步由蒙古南下影响中国东北和华北地区,最后到达中国东部海域。 相似文献
5.
南海大尺度动力场年循环和年际变化 总被引:8,自引:2,他引:8
应用COADS风应力、Levitus温度资料,描述南海上层海洋动力场的年循环及其与热力场之间的关系和南海大尺度动力场的年际变化。针对冬、夏2个季节,分析Sverdrup环流场与上层海温之间的关系。研究发现,上层海温变化与上层海洋环流基本结构非常相似,即上层海温变化在一定程度上反映了南海Sverdrup平衡,而且随着浓度的增加,平均海温场与流函数场之间的对应关系更好。本文还着重分析了El Nino期间和La Nina期间的南海异常流函数场。研究发现,异常流函数场在El Nino期间的夏季主要是强化南海自身的环流结构,即强化南部反气旋式涡流(gvre)和强化北部气旋式涡流;冬季则削弱整个南海的气旋式流场。LaNina期间对夏季环流态的影响主要集中在南海北部,即削弱北部气旋式涡流,而对于南海南部的影响甚微;冬季则强化整个南海的气旋式流场。 相似文献
6.
南海QuikSCAT海面风场变化特征分析 总被引:4,自引:0,他引:4
基于QuikSCAT海面风场产品,对海面风场资料进行了EOF分析和随机动态分析,以此分析南海海面风场的变化特征。研究发现:海面原始风场风速季节变化最为明显,其变化占总变化方差的59.1%,黑潮的季节变化通过海气相互作用对南海局地风场有较明显的影响;原始风场第三模态及异常风场第二模态时间变化函数与SOI和PDO弱相关,且异常风场第二模态时间变化函数谱分析结果主要呈现5年的周期变化,南海海面风场变化与年际振荡有关;南海大部分海区风速呈现增长的趋势,但增长速率较小;风速增大最快的区域是台湾海峡以南海域和北部湾,增长速度达到0.05 ms-1a-1。 相似文献
7.
基于向外长波辐射、降水、大气再分析资料和 HYCOM(HYbridCoordinateOcean Model)盐度等资料,研究了 MJO(Madden-JulianOscillation,热带大气季节内振荡)对南海夏季降水的调制,并初步探讨了其对海洋表层盐度的影响。结果显示:MJO 对南海夏季降水有显著的调制作用,导致南海降水具有强的季节内变化,其最显著周期为45d。降水季节内信号在泰国湾北部、吕宋岛以西和台湾岛西南等迎风坡区域较强,而在越南外海的安南山脉背风区域较弱,且降水信号会随着 MJO 信号向东北方向移动。MJO 对流抑制(活跃)中心所在区域,低层大气辐聚减弱(增强),中层大气对流减弱(增强),导致降水减少(增加);此外,MJO 对流抑制(活跃)中心伴随的反气旋式(气旋式)环流会改变风场,风场减弱(增强)使得迎风区域的降水减少(增加)。MJO 引起的降水异常进一步影
响南海盐度,南海表层盐度也有明显的季节内变化特征,其显著周期和降水基本一致,为47d,且盐度异常信号也随降水异常向东北移动。本研究结果有助于进一步了解南海降水和表层盐度的季节内变化特征。 相似文献
8.
基于向外长波辐射、降水、大气再分析资料和 HYCOM(HYbridCoordinateOcean Model)盐度等资料,研究了 MJO(Madden-JulianOscillation,热带大气季节内振荡)对南海夏季降水的调制,并初步探讨了其对海洋表层盐度的影响。结果显示:MJO 对南海夏季降水有显著的调制作用,导致南海降水具有强的季节内变化,其最显著周期为45d。降水季节内信号在泰国湾北部、吕宋岛以西和台湾岛西南等迎风坡区域较强,而在越南外海的安南山脉背风区域较弱,且降水信号会随着 MJO 信号向东北方向移动。MJO 对流抑制(活跃)中心所在区域,低层大气辐聚减弱(增强),中层大气对流减弱(增强),导致降水减少(增加);此外,MJO 对流抑制(活跃)中心伴随的反气旋式(气旋式)环流会改变风场,风场减弱(增强)使得迎风区域的降水减少(增加)。MJO 引起的降水异常进一步影
响南海盐度,南海表层盐度也有明显的季节内变化特征,其显著周期和降水基本一致,为47d,且盐度异常信号也随降水异常向东北移动。本研究结果有助于进一步了解南海降水和表层盐度的季节内变化特征。 相似文献
9.
利用长时间序列的卫星观测数据,对南海海域的风、浪场时空分布及其相互关系进行了分析。结果显示,海面风距平场VEOF分解后得到的第一模态具有明显的季节变化,即季风特征,说明季风是影响整个南海风速的主要因素;第二模态具有较强的区域变化特征,是季风转换时期的距平场特征;第三模态反映的是海面风距平场受陆地地形影响所表现的分布特征。有效波高距平场EOF分解后得到的第一模态、第二模态与风距平场的前2个模态的空间分布较为相似,并且,风、浪距平场第一模态间的相关系数达0.76,均说明南海作为边缘海其波浪场与风场变化有很好的相关性。有效波高第三模态的分布与风场的第三模态相关性较弱,反映的是受海底地形影响所表现的分布特征。 相似文献
10.
大气低层风场对南海海温的影响及其与季风的关系 总被引:3,自引:0,他引:3
利用1960-1999年月平均海表温度资料和大气低层风场资料,分析了南海海表温度与局地风场之间的关系及其季节变化特征,讨论了局地风场对南海海温的影响与季风的联系.结果表明,南海海表温度异常与局地风场异常之间的关系具有明显的季节变化特征,南海海表温度异常在夏季与纬向风异常呈明显的负相关,在冬季与经向风异常呈明显的正相关,这种季节变化与东亚季风特性(即盛行风存在明显的季节变化)密切相关.为南海海表温度监测预测提供气候背景,从而也解释了过去在大气低层风速与南海海表温度异常相关性方面不同研究结果存在差异的原因. 相似文献
11.
基于南沙群岛海域综合科学考察11个航次的实测资料,研究了南沙群岛海域的混合层深度季节变化特征。研究结果表明,南沙群岛海域混合层深度存在明显的季节变化,并且与季风和海表热通量的变化密切相关。春季,风速较小且风向不稳定,海面得到的净热通量全年最大,上层水体层结稳定,混合层深度较小;夏季,南海西南季风盛行,上层为反气旋式环流,海面得到的净热通量减少,混合层呈加深的趋势;秋季,海面净热通量继续减少,混合层深度达到最大值;冬季,东北季风驱动下形成的上层气旋式环流引起深层冷水的上升,限制了混合层的加深。 相似文献
12.
孟加拉湾上层环流研究综述 总被引:2,自引:0,他引:2
综述了孟加拉湾上层环流研究的主要成果并指出,研究海区环流与季风转换不完全同步。在西南季风期间,南、北海区各有一气旋式环流;在秋季季风过渡期间,出现海湾尺度的气旋式环流;在东北季风期间,气旋式环流减弱北移,南部则为一反气旋式环流控制;春季与秋季的情形相反,整个湾出现一海湾尺度的反气旋式环流。研究海区环流的变异主要受季风、赤道远地作用和浮力通量等复杂外源作用的影响。东印度沿岸流的季节变化与季风转换也不同步,局地风、内部Ekman抽吸、远地沿岸风及赤道远地作用的影响对沿岸流周年变化有重要作用。孟加拉湾上层环流年际变化显著,此年际变化主要受赤道风场的影响。 相似文献
13.
Annual and interannual variations of sea-level anomaly in the Bay of Bengal and the Andaman Sea 总被引:2,自引:2,他引:0
Annual and interannual variations of sea-level anomaly (SLA) in the Bay of Bengal and the Andaman Sea are investigated using altimeter-derived SLA data from 1993 to 2003. It is found that the SLA annual variation in the study area can be divided into three phases with distinctive patterns. During the southwest monsoon (May-September), positive SLA presents in the equatorial region and extends northward along the eastern boundary of the bay, and the SLA distribution in the interior bay appears to be high in the east and low in the west with two cyclonic cells developing in the north and south of the western bay respectively, between which an anticyclonic cell exists. During the early northeast monsoon (October-December), the whole bay is dominated by a large cyclonic cell with the pattern of high SLA in the east and low in the west still retained, and the SLA distribution outside the bay is changed in response to the reversal of the Indian Monsoon Current (IMC) in November. During the late northeast monsoon (January-April), a large anticyclonic cell of SLA develops in the bay with negative SLA prevailing in the equatorial region and extending northward along the eastern boundary of bay. Therefore, the SLA distribution in the interior bay reverses to be high in the west and low in the east. It is suggested that the SLA annual variation in the bay is primarily driven by the local wind stress curl, involving Sverdrup balance while the abrupt SLA variation during the peak of northeast monsoon may be partly caused by the semiannual fluctuation of wind in the equatorial region. This fast adjustment in the interior bay is induced by the upwelling coastal Kelvin wave excited by the decay of Wyrtki jet during December through January. Besides the annual variation, in the bay, there are obvious SLA fluctuations with the periods of 2 and 3~7 a, which are driven by the interannual variability of large-scale wind field in the equatorial region. The coastal Kelvin wave also provides an important link for the SLA interannual variation between the equatorial region and the interior bay. It is found that the El Nio-Southern Oscillation (ENSO)-induced influence on the SLA interannual variation in the interior bay is stronger than the Indian Ocean dipole (IOD) with the associated pattern of low sea-level presenting along the periphery of the bay and high sea-level in the northeast of Sri Lanka. 相似文献
14.
Patterns of upper layer circulation variability in the South China Sea from satellite altimetry using the self-organizing map 总被引:2,自引:2,他引:0
Patterns of the South China Sea (SCS) circulation variability are extracted from merged satellite altimetry data from October 1992 through August 2004 by using the self-organizing map (SOM). The annual cycle, seasonal and inter-annual variations of the SCS surface circulation are identified through the evolution of the characteristic circulation patterns. The annual cycle of the SCS gener- al circulation patterns is described as a change between two opposite basin-scale SW-NE oriented gyres embedded with eddies: low sea surface height anomaly (SSHA) (cyclonic) in winter and high SSHA (anticyclonic) in summer half year. The transition starts from July--August (January--February) with a high (low) SSHA tongue east of Vietnam around 12°~14° N, which de- velopa into a big anticyclonic (cyclonic) gyre while moving eastward to the deep basin. During the transitions, a dipole structure, cyclonic (anticyclonic) in the north and anticyclonic (cyclonic) in the south, may be formed southeast off Vietnam with a strong zonal jet around 10°~12° N. The seasonal variation is modulated by the interannual variations. Besides the strong 1997/1998 e- vent in response to the peak Pacific El Nino in 1997, the overall SCS sea level is found to have a significant rise during 1999~ 2001, however, in summer 2004 the overall SCS sea level is lower and the basin-wide anticyclonic gyre becomes weaker than the other years. 相似文献
15.
Propagation of Rossby Waves over Ridges Excited by Interannual Wind Forcing in a Western North Pacific Model 总被引:1,自引:4,他引:1
Numerical experiments with a multi-level general circulation model have been performed to investigate basic processes of westward
propagation of Rossby waves excited by interannual wind stress forcing in an idealized western North Pacific model with ocean
ridges. When the wind forcing with an oscillation period of 3 years is imposed around 180°E and 30°N, far from Japan, barotropic
waves excited by the wind can hardly cross the ridges, such as the Izu-Ogasawara Ridge. On the other hand, a large part of
the first-mode baroclinic waves are transmitted across the ridges, having net mass transport. The propagation speed of the
first-mode baroclinic wave is accelerated (decelerated) when an anticyclonic (cyclonic) circulation is formed at the sea surface,
due to a deeper (shallower) upper layer, and to southward (slightly northward) drift of the circulation. Thus, when the anticyclonic
circulation is formed on the northern side of the cyclonic one, they propagate almost together. The second-mode baroclinic
waves converted from the first-mode ones on the ridges arrive south of Japan, although their effects are small. The resulting
volume transport variation of the western boundary current (the Kuroshio) reaches about 60% of the Sverdrup transport variability
estimated from the wind stress. These characteristics are common for the interannual forcing case with a longer oscillation
period. In the intraseasonal and seasonal forcing cases, on the other hand, the transport variation is much smaller than those
in the interannual forcing cases.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
16.
Seasonal and interannual variability of the Subtropical Countercurrent (STCC) in the western North Pacific are investigated
using observations by satellites and Argo profiling floats and an atmospheric reanalysis. The STCC displays a clear seasonal
cycle. It is strong in late winter to early summer with a peak in June, and weak in fall. Interannual variations of the spring
STCC are associated with an enhanced subtropical front (STF) below the surface mixed layer. In climatology, the SST front
induces a band of cyclonic wind stress in May north of the STCC on the background of anticyclonic curls that drive the subtropical
gyre. The band of cyclonic wind and the SST front show large interannual variability and are positively correlated with each
other, suggesting a positive feedback between them. The cyclonic wind anomaly is negatively correlated with the SSH and SST
below. The strong (weak) cyclonic wind anomaly elevates (depresses) the thermocline and causes the fall (rise) in the SSH
and SST, accelerating (decelerating) STCC to the south. It is suggested that the anomalies in the SST front and STCC in the
preceding winter affect the subsequent development of the cyclonic wind anomaly in May. Results from our analysis of interannual
variability support the idea that the local wind forcing in May causes the subsequent variations in STCC. 相似文献
17.
Interannual variability of the Kuroshio intrusion in the South China Sea 总被引:13,自引:1,他引:13
Michael J. Caruso Glen G. Gawarkiewicz Robert C. Beardsley 《Journal of Oceanography》2006,62(4):559-575
The interannual variability of intrusions of the Kuroshio into the South China Sea (SCS) is investigated using satellite remote
sensing data supported by in-situ measurements. The mesoscale circulation of the SCS is predominantly wind-forced by the northeast
winter and southwest summer monsoons. Although the region has been studied extensively, considerable uncertainty remains about
the annual and interannual mesoscale nature of the circulation. The frequency and characteristics of Kuroshio intrusions and
their effect on circulation patterns in the northeast SCS are also not well understood. Satellite observations of Sea Surface
Temperature (SST) from the Tropical Rainfall Measuring Mission (TRMM) and the Advanced Very High Resolution Radiometer (AVHRR)
and Sea Surface Height Anomalies (SSHA) from TOPEX/ Poseidon for the period 1997–2005 are used here to analyze the annual
and interannual variability in Kuroshio intrusions and their effects on the region. Analysis of SST and SSHA shows the formation
and characteristics of intrusions vary considerably each year. Typically, the intrusion occurs in the central region of Luzon
Strait and results in an anticyclonic circulation in the northeastern SCS. However, in some years, the intrusion is located
in the northern portion of Luzon Strait and a cyclonic intrusion results. Wind stress and wind stress curl derived from the
National Aeronautics and Space Administration (NASA) QuikSCAT satellite scatterometer are used to evaluate the relationship
between wind stress or wind stress curl and the presence of winter Kuroshio intrusions into the SCS. 相似文献
18.
本文使用基于热成风速度的涡旋识别拓展方法,通过海表面温度数据对黑潮延伸体区域50-100公里涡旋进行研究,发现50-100公里涡旋主要分布在黑潮延伸体流轴两侧,气旋涡和反气旋涡的寿命、半径分布具有一致性。气旋涡多出现在35°N以北,反气旋涡在35°N以南比较集中,与尺度较小的中尺度涡旋分布特征较为相似。冬夏两季涡旋地理分布存在一定差异,主要与不同季节该区域海表温度梯度及风应力旋度的变化有关。35°N以南50-100公里涡旋数量的季节性变化与风速大小的季节性变化存在明显的正相关性。35°N以南50-100公里涡旋三倍半径内风速异常和风应力旋度归一化表明,气旋涡对应风速负异常而反气旋涡对应风速正异常,反气旋涡的产生依赖于风应力负旋度,气旋涡的生成与风应力正旋度有关。 相似文献
19.
20.
本文使用基于热成风速度的涡旋识别拓展方法,通过海表面温度数据对黑潮延伸体区域50~100 km涡旋进行研究,发现50~100 km涡旋主要分布在黑潮延伸体流轴两侧,气旋涡和反气旋涡的寿命、半径分布具有一致性。气旋涡多出现在35°N以北,反气旋涡在35°N以南比较集中,与尺度较小的中尺度涡旋分布特征较为相似。冬夏两季涡旋地理分布存在一定差异,主要与不同季节该区域海表温度梯度及风应力旋度的变化有关。35°N以南50~100 km涡旋数量的季节性变化与风速大小的季节性变化存在明显的正相关性。35°N以南50~100 km涡旋三倍半径内风速异常和风应力旋度归一化表明,气旋涡对应风速负异常而反气旋涡对应风速正异常,反气旋涡的产生依赖于风应力负旋度,气旋涡的生成与风应力正旋度有关。 相似文献