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1.
南海混合层深度的季节和年际变化特征 总被引:1,自引:0,他引:1
利用1871-2008年SODA资料和月平均的Levitus资料计算了南海混合层深度(MLD)的季节及年际变化特征.资料分析表明:季风通过流场调整对南海MLD的时空分布特征有显著的影响.南海MLD的距平变化总体上呈上升趋势,南海南部MLD的距平变化趋势和北部的有显著差异,特别在1955年后北部整体呈下降趋势而南部呈上升趋势,二者的显著周期北部为2-3年,南部与整个区域平均的基本相似有2-6年的显著周期.SOI指数对滞后的南海各个区域有较好的相关性.EOF分析表明第一模态整体呈单极型最大变率分布在南海南部,由南往北逐渐减小显著周期2-3年变化为主;第二模态呈偶极子型,显著周期以2-5年变化为主.回归分析表明南海南部深水区域呈现增深的趋势,而吕宋海峡至南海北部陆架区呈变浅趋势,滑动t检验表明南海MLD有6个显著的突变年份. 相似文献
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1993—2006年北太平洋海平面变化特征及影响因素 总被引:2,自引:0,他引:2
利用1993—2006年间卫星高度计资料分析北太平洋海平面的变化特征,结合同期上层海洋温度、盐度数据以及风应力资料分析比容海平面和风对海平面变化的影响。结果显示:1993—2006年北太平洋上升海域主要位于洋盆西侧中低纬度海域,高纬度海域及大洋东侧的中低纬度海域海平面呈下降趋势;同期比容海平面线性速率的空间分布与海平面相似。整个北太平洋海平面高度平均线性上升速率为2.9 mm/a,比容海平面平均线性上升速率为1.4 mm/a。比容变化对海平面上升趋势的贡献为47.5%。北太平洋海平面的季节变化占绝对优势,主要为1和0.5 a周期,对海平面距平做EOF,其第一和第三模态为季节模态。海平面季节变化的影响因素中,比容变化与海平面有相同的季节变化周期,比容海平面距平EOF的第一和第三模态为季节模态,分别与海平面的第一和第三模态空间分布相似,时间系数相关性好,比容变化在海平面季节特征中起到最主要作用。另一个因素风场主要通过Ekman抽吸和Rossby波的西传影响海平面的分布,其季节特征对海平面的季节特征有影响。北太平洋海平面也具有28个月的年际变化周期,海平面距平EOF第二和第四模态表现出年际变化特征。比容变化也具有28个月的显著周期,其距平场的第二和第四模态为年际变化模态,其中第二模态与海平面第二模态空间分布相似,时间系数相关性很好,海平面年际变化中比容起到重要影响。 相似文献
3.
利用SODA(Simple Ocean Data Assimilation)再分析资料,分析了南海北部深水海域温度及盐度的季节和年际变化特征,讨论了季节及年际变化时间尺度上黑潮通过吕宋海峡对南海北部温、盐场的影响.资料分析表明:南海北部深水海域温、盐场存在明显的季节及年际变化特征.在气候平均态下,吕宋海峡处黑潮对南海北部温、盐场的影响主要存在于119°E以东;黑潮对南海的入侵程度在冬季最大,可影响到118°E附近;在秋季最小.吕宋海峡以西的温度水平梯度在秋季最弱,而盐度水平梯度则在夏季最弱.在吕宋海峡处黑潮形变的南侧,温、盐场年际变化信号最强.通过EOF(Empirical Othorgnal Function)分析,发现南海北部深水海域盐度和温度场第一模态的最大变率均分布在吕宋海峡处黑潮形变的南部,且均具有2~5 a的年际变化周期.另外,在年际变化时间尺度上,南海北部深水海域盐度场受黑潮形变的影响较大,在黑潮流量大的年份吕宋海峡处盐度值较低,在黑潮流量小的年份吕宋海峡处盐度值较高,而温度场则和Nino3.4指数呈明显的负相关变化. 相似文献
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5.
本文基于粗分辨率卫星数据和中尺度分辨率ROMS模型数据,通过一种较新的循环平稳经验正交函数(CSEOF)方法,分析南海表面温度的季节变化与年际变化,其中南海表面温度的第一模态和第二模态分别代表南海温度的季节变化信号和随ENSO变化的信号。卫星与模型的第一模态的空间分布较为一致,南海北部相对南部具有更强的季节变化,第一模态时间序列主成分与Nino3指数具有一定相关性,但相关系数小于30%。卫星与模型第二模态时间序列主成分与Nino3相关性较高,均大于50%,落后Nino3指数7个月。通过对比模型与卫星结果发现,中尺度过程的引入仅使第二模态空间分布更为复杂,而对第一模态的季节变化及与ENSO信号的相关性并没有显著影响。赤道太平洋温度异常通过大气环流无延迟的影响南海的云层覆盖和蒸发,进而影响南海表面的短波辐射和潜热通量,混合层中垂向混合和夹带过程可能是阻碍南海表面温度过快响应净热通量改变的原因。 相似文献
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通过对1950-2012年的南海混合层盐度数据进行分析,发现影响南海北部和南部盐度季节变化的最主要因素存在很大的差异.在南海北部,影响混合层盐度季节变化的最主要因素是蒸发降水,其次是水平平流.随着逐步南移,蒸发降水对盐度季节变化的影响递减,水平平流的影响逐渐增大;而在南海南部,水平平流的作用超过蒸发降水成为影响盐度的季节变化的最主要因素.在整个南海区域,冬季海水垂直混合变强,混合层变厚,下层高盐海水进入混合层,使混合层海水盐度变高,从而对冬季海水盐度的上升趋势产生促进作用;夏季南海北部混合层底存在上升流,南海东南部由于Ekman输运导致混合层变厚,都会将混合层以下高盐海水带入混合层,使混合层海水盐度变高,从而对夏季海水盐度下降趋势产生阻碍作用,但垂直混合对盐度季节变化的影响不大,远小于蒸发降水和水平平流. 相似文献
7.
利用1993-2010年间的卫星高度计资料,用EOF方法及小波分析研究了黑潮延伸体区域的海平面异常和中尺度涡的时空变化特征.研究结果表明:海平面EOF第一模态是季节模态,与该海域风应力旋度第一模态类似,相关系数达0.65.EOF第二模态主要反映了黑潮南部次级环流的变化情况,显著性周期是8-10年.通过相关分析发现黑潮延伸体南部次级环流的年代际变化与PDO有关,同时它又与风应力旋度第二模态有关;该海域的海面高度受到北太平洋东部SSH信号西传的影响,信号的传播需要大约3-4年时间.EOF第三模态是黑潮弯曲模态.日本南部的气旋涡和反气旋涡可以表征黑潮弯曲的形成,而且弯曲强度和涡的持续时间、强度和位置有关. 相似文献
8.
利用1979—2017年共39 a欧洲中期天气预报中心(ECMWF)海表面10 m风场资料,采用经验正交函数方法(EOF)、小波时频特征分析等方法分析了南海近海面风场变化特征及其对ENSO的响应。结果表明:南海近海面风场第一模态海表面平均风速呈减小趋势,呈现年代际变化,且与ENSO相关,但相关性在1990年后趋于减小;第二模态中南海北部和南部平均风速呈减小趋势,中部增大;第三模态中南海中部海表面平均风速趋于减小,北部和南部增大,第二和第三模态均表现为年际变化,且均与ENSO显著相关,近年来ENSO与第三模态的相关性逐渐增强。春季南海表面平均风速从南到北逐渐增加;夏季在越南沿岸部分海域仍有一个风速极大值中心,从该海域向四周逐渐减小,整片海域风向均是西南风;秋季由南向北依次增加;冬季南海整片海域风速都较大,越南沿岸和我国东沙群岛海域存在两个极大值中心。 相似文献
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南海盐度锋的年际变化特征分析 总被引:1,自引:0,他引:1
为了探究南海表层5 m盐度锋的年际变化特征,应用50年(1958—2007年)的SODA月平均资料,采用均方差和经验正交函数进行研究。结果表明,盐度锋年际变化显著的区域集中在北部湾、海南岛以东、南海北部、吕宋海峡、东马来西亚西北部和越南最南端;第一模态和第二模态时间系数变化趋势均表明南海盐度锋强度在逐渐减小;前者呈单极子型空间分布,后者空间分布型则为偶极子型。第一模态时间系数功率谱分析表明该模态存在3—5年和7—16年的周期,Morlet小波分析显示1965—2000年该模态主要存在4年、9年和12年左右的周期。第一模态确立的3个负位相中心区域(海南岛以东、吕宋海峡和越南最南端)的均值变化趋势一致,强度都在逐渐增大,具有同位相变化特征;第二模态时间系数功率谱分析表明该模态存在3年、5年和8—12年的周期。Morlet小波分析表明1962—2001年期间该模态存在3年、5年和9—12年的周期。第二模态找出的两个正负位相中心分别在东马来西亚西北部和南海北部,前者盐度锋强度在逐渐减小,而后者强度却在持续增大,强度的年际变化呈现反位相变化特征。 相似文献
10.
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
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基于ROMS模型数值研究南海温跃层的季节变化 总被引:2,自引:0,他引:2
On the basis of the regional ocean modeling system (ROMS), the seasonal variations of the thermocline in the South China Sea (SCS) were numerically investigated. The simulated hydrodynamics are in accordance with previous studies: the circulation pattern in the SCS is cyclonic in winter and anticyclonic in summer, and such a change is mostly driven by the monsoon winds. The errors between the modeled temperature profiles and the observations obtained by cruises are quite small in the upper layers of the ocean, indicating that the ocean status is reasonably simulated. On the basis of the shapes of the vertical temperature profiles, five thermocline types (shallow thermocline, deep thermocline, hybrid thermocline, double thermocline, and multiple thermocline) are defined herein. In winter, when the northeasterly monsoon prevails, most shallow shelf seas in the northwest of the SCS are well mixed, and there is no obvious thermocline. The deep region generally has a deep thermocline, and the hybrid or double thermocline often occurs in the areas near the cold eddy in the south of the SCS. In summer, when the southwesterly monsoon prevails, the shelf sea area with a shallow thermocline greatly expands. The distribution of different thermocline types shows a relationship with ocean bathymetry: from shallow to deep waters, the thermocline types generally change from shallow or hybrid to deep thermocline, and the double or multiple thermocline usually occurs in the steep regions. The seasonal variations of the three major thermocline characteristics (the upper bound depth, thickness, and intensity) are also discussed. Since the SCS is also an area where tropical cyclones frequently occur, the response of thermocline to a typhoon process in a short time scale is also analyzed. 相似文献
12.
冬季婆罗洲岛西北沿岸上升流的时空特征及机理研究 总被引:1,自引:0,他引:1
Winter coastal upwelling off northwest Borneo in the South China Sea(SCS) is investigated by using satellite data, climatological temperature and salinity fields and reanalysis data. The upwelling forms in December, matures in January, starts to decay in February and almost disappears in March. Both Ekman transport induced by the alongshore winter monsoon and Ekman pumping due to orographic wind stress curl are favorable for the upwelling. Transport estimates demonstrate that the month-to-month variability of Ekman transport and Ekman pumping are both consistent with that of winter coastal upwelling, but Ekman transport is two times larger than Ekman pumping in January and February. Under the influence of El Ni?o-Southern Oscillation(ENSO), the upwelling shows remarkable interannual variability: during winter of El Ni?o(La Ni?a) years, an anticyclonic(a cyclonic) wind anomaly is established in the SCS, which behaves a northeasterly(southwesterly) anomaly and a positive(negative) wind stress curl anomaly off the northwest Borneo coast, enhancing(reducing) the upwelling and causing anomalous surface cooling(warming) and higher(lower) chlorophyll concentration. The sea surface temperature anomaly(SSTA) associated with ENSO off the northwest Borneo coast has an opposite phase to that off southeast Vietnam, resulting in a SSTA seesaw pattern in the southern SCS in winter. 相似文献
13.
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
14.
XIAO Xianjun WANG Dongxiao ZHOU Wen ZHANG Zuqiang QIN Yinghao HE N ZENG Lili 《海洋学报(英文版)》2013,32(9):30-37
The seasonal variation of mixing layer depth(MLD) in the ocean is determined by a wind stress and a buoyance flux.A South China Sea(SCS) ocean data assimilation system is used to analyze the seasonal cycle of its MLD.It is found that the variability of MLD in the SCS is shallow in summer and deep in winter,as is the case in general.Owing to local atmosphere forcing and ocean dynamics,the seasonal variability shows a regional characteristic in the SCS.In the northern SCS,the MLD is shallow in summer and deep in winter,affected coherently by the wind stress and the buoyance flux.The variation of MLD in the west is close to that in the central SCS,influenced by the advection of strong western boundary currents.The eastern SCS presents an annual cycle,which is deep in summer and shallow in winter,primarily impacted by a heat flux on the air-sea interface.So regional characteristic needs to be cared in the analysis about the MLD of SCS. 相似文献
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南海混合层年循环特征 总被引:22,自引:4,他引:22
通过分析Levitus1994版气候平均温盐资料,得到南海混合层的时空分布特征,剖析了混合层浓度及其内部温度的季节变化规律。资料分析表明:季风通风流场调整对南海混合层的时空分布着明显的影响。这种影响的复杂性在于它不但通过海洋表层Ekman效应来影响混合层深度,而且还通过大尺度环流造成的幅散或辐合来限制或促进混合层深度的发展。研究发现混合层深度与混合层内温度存在着如下关系:夏季最大混合层的形成是28℃等温线与混合层底达到相互贴合的过程;冬季最大混合层的形成是28℃水体完全消失并且等温度线与混合层达到相交最多、相交最为垂直的过程,这时对应着冬季南海北部温跃层的通风;大于或等于28℃的水体总是位于混合层以内。 相似文献
16.
南海U形海疆国界线(简称南海U形线)是我国的南海国界线。该研究分析多源卫星遥感和GIS数据,系统研究南海U形海疆线水域的水深地形和环境生态要素,并重点分析2014年生态要素的季节变化,首次整体展现了南海U形线立体水深分布特征。根据海底地形的平缓、波峰、波谷和递增四大特征,将南海U形线分为东北、西北、东、西和南区5个区间。南海U形线总长大于4 000 km。西北区和南区的水深浅且变化平缓(<1 000 m),西区水深呈波峰分布(平均2 303 m),东区水深由南向北递增(>2 000 m);东北区水深最深且呈波谷分布(平均3 535 m)。南海U形线的5个区间,西北区与北部湾盆地、西区与越东断裂、南区与曾母盆地、东区与南海海槽、东北区与马尼拉海沟地形构造相吻合。研究发现季风对南海U形线5个区间海洋环境季节性变化有明显影响:西北区和东北区海表温度温差大,呈冬季最低夏季最高,混合层深度冬季最深春季最浅,海表流场和海表盐度季节变化小,但西北区海表叶绿素a浓度冬季爆发,其余季节呈对数分布,而东北区冬季区内中部略有增长;西区、南区和东区海表温度盐度季节变化小,海表风场和混合层深度冬季最强春季最弱,但海表叶绿素a浓度西区季节变化小,南区区内中部冬季增长明显,东区区内南部冬季小幅增长。西北区和南区(浅地形区)呈相似的季节分布。研究阐明了5个区间具有各自明显的区域性海洋环境特征:西北区海表温度和海表叶绿素a浓度的季节变化最大、西区混合层深度季节变化最大、南区海表流场季节变化最大、东区海表盐度季节变化最大、东北区风场变化大但海表叶绿素a浓度季节变化小。研究显示,南海U形线上的台风路径时空分布南北差异大,东西不均。1945—2016年共604个台风跨过南海U形线,年均8个,路径集中在东北、西北、东3个区,112.3°E以东台风537个,112.3°E以西415个。南海U形线东北区的生态环境受台风"风泵效应"影响最大。1991—2000年为台风多发期,跨线台风年均达11个。研究提出的南海U形海疆线5区间分法,具有科学意义和实践指导作用。 相似文献
17.
The low-frequency variability of the shallow meridional overturning circulation(MOC) in the South China Sea(SCS) is investigated using a Simple Ocean Data Assimilation(SODA) product for the period of 1900–2010. A dynamical decomposition method is used in which the MOC is decomposed into the Ekman, external mode, and vertical shear components. Results show that all the three dynamical components contribute to the formation of the seasonal and annual mean shallow MOC in the SCS. The shallow MOC in the SCS consists of two cells: a clockwise cell in the south and an anticlockwise cell in the north; the former is controlled by the Ekman flow and the latter is dominated by the external barotropic flow, with the contribution of the vertical shear being to reduce the magnitude of both cells. In addition, the strength of the MOC in the south is found to have a falling trend over the past century, due mainly to a weakening of the Luzon Strait transport(LST) that reduces the transport of the external component. Further analysis suggests that the weakening of the LST is closely related to a weakening of the westerly wind anomalies over the equatorial Pacific, which leads to a southward shift of the North Equatorial Current(NEC) bifurcation and thus a stronger transport of the Kuroshio east of Luzon. 相似文献
18.
The steady response of the ventilated thermocline to an increase in Ekman pumping is investigated, focusing on the effect
of the mixed layer depth distribution on the subsurface density anomaly. We consider only the subtropical gyre, and the mixed
layer is assumed to be deep in the northwest and shallow elsewhere with a narrow transition zone separating the deep and shallow
mixed layer regions. At the intersection of this narrow transition zone and the outcrop line, low potential vorticity fluid
is subducted into and ventilates the thermocline. In such a situation, an enhancement of the Ekman pumping confined to the
northern subtropical gyre leads to pronounced subsurface cold anomalies in the southern subtropics, which is free of anomalous
forcing. These density anomalies are much greater than those that occur when either the mixed layer depth is zonally uniform
or the Ekman pumping is enhanced in the whole subtropical gyre. They are caused by anomalous changes in the trajectory of
the low potential vorticity fluid in response to anomalous Sverdrup flow.
This revised version was published online in July 2006 with corrections to the Cover Date. 相似文献
19.
A P - vector method is optimized using the variational data assimilation technique(VDAT). The absolute geostrophic velocity fields in the vicinity of the Luzon Strait (LS) are calculated, the spatial structures and seasonal variations of the absolute geostrophic velocity field are investigated. Our results show that the Kuroshio enters the South China Sea (SCS) in the south and middle of the Luzon Strait and flows out in the north, so the Kuroshio makes a slight clockwise curve in the Luzon Strait, and the curve is strong in winter and weak in summer. During the winter, a westward current appears in the surface, and locates at the west of the Luzon Strait. It is the north part of a cyclonic gyre which exits in the northeast of the SCS; an anti-cyclonic gyre occurs on the intermediate level, and it exits in the northeast of the SCS, and an eastward current exits in the southeast of the anti-cyclonic gyre. 相似文献
20.
南海东北部亚中尺度过程时空分布特征 总被引:6,自引:3,他引:3
基于高分辨率模型2009-2012年的模拟结果,本文对南海东北部亚中尺度过程的时空分布特征进行了研究。模拟结果表明,南海东北部上层广泛存在着相对涡度接近于局地行星涡度的亚中尺度过程。统计结果发现,亚中尺度过程的相对涡度的分布具有着明显的非对称性,即正涡度明显强于负涡度。这意味着相比于负涡度,具有正涡度的亚中尺度过程要更为活跃,而这主要是由离心不稳定导致。同时,亚中尺度过程在时间分布上表现出明显的冬强夏弱的季节变化特征。通过对该海区亚中尺度过程可能生成机制的分析发现,该季节变化与流场拉伸和混合层的厚度有着密切关系,冬季更强的流场拉伸和更深的混合层有利于通过锋生过程和混合层不稳定为亚中尺度过程生成提供更多的能量。 相似文献