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1.
根据北黄海断面1976~2015年历年8月温度、盐度与长岛气候要素资料,采用旋转经验正交函数(REOF)、最大熵谱分析和延迟相关分析等方法,研究了北黄海断面夏季温度、盐度年际变化时空模态与气候响应.断面温度主要有4种时空模态:第一、二模态为海洋因素影响的年际变化分量,渤海断面夏季温度分量和7月太平洋年代际振荡(PDO)指数的线性与非线性作用是主要影响因素.第三、四模态为海洋与大气因素影响的年际变化分量,渤海断面夏季温度分量、断面冬季表层平均温度、7月风驱环流强度和5月PDO指数的线性和非线性作用是主要影响因素.断面盐度主要有4种时空模态:第一模态为海洋与大气因素影响的年际变化分量,渤海夏季盐度、夏季降水量及断面冬季表层盐度是主要影响因素;8月纬向风驱环流是次要影响因素.第二至四模态为大气因素影响的年际变化分量,7、8月风驱环流强度和夏季降水量是主要影响因素.北黄海夏季风驱环流分布是北黄海断面夏季温盐年际平均分布的主要影响因素.断面温盐垂直层结年际变化为准平衡态周期年际变化.北黄海断面冷水团月平均温度和面积为准平衡态周期年际变化,断面温度第三模态、断面冬季表层平均温度是断面冷水团月强度年际变化的主要影响因素,7月PDO指数是非线性影响因素.北黄海断面冷水团月平均盐度为显著线性低盐趋势周期年际变化,断面盐度的第一至三模态以及渤海断面夏季盐度分量的线性和非线性作用是冷水团月平均盐度年际变化的主要影响因素.北黄海断面夏季冷水团中平均温度、盐度的长期变化趋势是不同的,不存在长期稳定的比例关系. 相似文献
2.
本文利用Argo海水盐度资料、海流同化数据和同期大气再分析数据,探讨热带太平洋盐度趋势变化和相关动力过程。Argo资料显示,2015?2017年热带太平洋出现显著的盐度异常(SAE),这是改变长期趋势的主要原因,表现为表层显著淡化和次表层咸化特征。这种盐度异常具有明显的区域性特征和垂直结构的差异,体现在热带太平洋北部海区(NTP)和南太平洋辐合区(SPCZ)表层淡化,盐度最大变幅为0.71~0.92,淡化可以达到混合层底;热带太平洋南部海区(STP)次表层咸化,最大变幅为0.46,主要发生在温跃层附近,期间盐度异常沿着等位密面从西向东扩展。平流和挟卷是与SAE密切相关的海洋动力过程,两者在NTP淡化海域有着持续而较为显著的影响,在SPCZ淡化、STP咸化海域后期贡献也较大,其中盐度平流对热带太平洋海区盐度变化起主要贡献。NTP淡化海区表层淡水通量和STP咸化海区密度补偿引起的混合也是SAE的重要影响因素。 相似文献
3.
全球海洋环流模式中上层海洋对表面强迫的响应和调整Ⅱ.年代际变率 总被引:6,自引:1,他引:5
利用一个较高分辨率的全球海洋环流模式在COADS 1945~1993年逐月平均资料的强迫下对海温和环流场进行了模拟,分析了北太平洋海温和环流场的年代际变化特征,同时诊断了1976-77年代际跃变过程中海温场变化的机制.模式模拟出了北太平洋海温年代际异常的主要模态以及1976-77年跃变前后的演变特征,模拟的北太平洋中部、加州沿岸和KOE区的海温异常的强度和演变趋势均和观测比较一致;同时,模式重现了分别始于20世纪70和80年代的中纬度海温异常信号沿等密度面向低纬地区的两次潜沉过程.在表层,流场的异常主要表现为与风应力异常基本符合Ekman关系的一个异常海洋涡旋,而整个上层海洋平均的流场异常则表现为两个海洋涡旋的异常,其中副热带海洋涡旋的异常的强度要显著于副极地海洋涡旋的异常,而副极地海洋涡旋异常出现的时间比副热带海洋涡旋晚3a左右的时间.对1976-77年前后3个区域上层海温各贡献项的诊断结果表明,北太平洋中部变冷主要是水平平流和热通量异常贡献的结果;而加州沿岸变暖主要归因于热通量的贡献;在KOE区,垂直平流、热通量和水平平流三者都起了重要作用,其中水平平流异常对这一区域海温年代际跃变出现的时间起了至关重要的作用. 相似文献
4.
本文利用2010—2019年东印度洋海洋学综合科学考察基金委共享航次数据、Argo(array for real-time geostrophic oceanography)和简单海洋再分析数据(simple ocean data assimilation,SODA),研究了赤道东印度洋次表层高盐水(subsurface high salinity water,SHSW)的年际变化,并探讨了其形成机制。仅限于春季的观测资料显示,来自阿拉伯海的高盐水位于东印度洋赤道断面次表层70~130m深度处,且具有显著的年际变化。基于月平均SODA资料的研究结果表明,不同时期SHSW盐度异常的变化趋势存在显著差异,2010—2015年趋势比较稳定,而2016—2019年则呈现出显著的上升趋势。通过对SHSW的回归分析表明,风场和次表层纬向流是控制该高盐水年际变化的主要因子。进一步的分析表明,赤道印度洋的东风异常导致水体向西堆积,产生东向压强梯度力,进而激发出次表层异常东向流,最终引起SHSW盐度异常升高。此动力关联在印度洋偶极子事件中尤为显著,这进一步反映了赤道东印度洋SHSW的年际变化受到印度洋偶... 相似文献
5.
《热带海洋学报》2017,(4)
采用Argo以及Aquarius卫星观测的海表盐度月平均资料研究了热带南印度洋海表盐度的季节变化特征。结果表明,在60°—80°E,5°—15°S海域海表盐度具有显著季节变化特征;夏半年盐度升高,冬半年盐度降低;但是其异常中心与降水异常中心不对应,降水不能解释盐度的季节变化。盐度收支分析显示,在夏半年,海表盐度增加的主要原因是经向平流将赤道地区的高盐输送至该地区;其中4—5月期间,海洋垂向卷夹作用加强,对海表高盐异常也起到重要作用。在冬半年,大气降水增加,海洋表层环流使得降水引起的局部低盐水体在该区域辐合;同时,向西的纬向平流将东南印度洋的低盐水体继续输送到该地区,二者对冬半年海表盐度降低都有重要贡献。 相似文献
6.
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.
8.
秘鲁上升流将富含营养盐的冷水带到表层,对沿岸的生态系统与渔业资源产生重要影响。厄尔尼诺事件对秘鲁上升流影响显著,而2014—2016年是近年来最强的厄尔尼诺事件之一。本文利用区域海洋模型ROMS,分析了秘鲁上升流在2014—2016年强厄尔尼诺期间的变化特征及影响因子。结果表明:2014与2015年春季,秘鲁沿岸表层海温出现正异常,主要与上升流减弱与平流增强造成的增暖有关,不同的是,2014年夏季平流增暖效应减弱,上升流增强,阻碍了海温正异常的继续发展;2015年夏季平流增暖效应持续,上升流作用被抑制,海温正异常持续至2016年春季;2014—2016年夏季秘鲁沿岸上升流增强与风应力增强有关;在冬春季节风应力减弱,利于产生上升流;2014和2015年春季出现下沉流,主要是由秘鲁潜流增强引起;风应力在2014—2016年无显著年际差异,潜流变化是产生厄尔尼诺年际差异的主导因素。 相似文献
9.
基于ECCO数据研究上层海洋盐度对印度洋偶极子事件的不对称响应 总被引:1,自引:0,他引:1
本文利用海洋观测资料和全球海洋环流模式数据(Estimating the Circulation and Climate of the Ocean, ECCO)研究了赤道印度洋上层海洋盐度的年际变化及其相关的海洋动力过程。研究结果表明,上层海洋盐度年际变化主要受印度洋偶极子事件影响,且盐度变化在正、负印度洋偶极子事件中存在不对称特征,其在偶极子正事件中表现更强烈。进一步研究表明,赤道印度洋上层盐度变化主要受纬向平流输运调控,尤其是Wyrtki急流对盐度变化有重要影响。在正印度洋偶极子事件期间,Wyrkti急流减弱甚至消失,流场负异常的强度明显较负偶极子事件期间的流场正异常强度强。印度洋偶极子存在正偏度是造成盐度和流场在正、负印度洋偶极子事件中存在不对称性的主要原因。 相似文献
10.
南海是西北太平洋最大的边缘海, 是联系北太平洋和北印度洋的关键通道。黑潮北上经过吕宋海峡时会将来自西太平洋的信号传入南海, 进而影响南海的水动力环境。研究了南海次表层盐度的空间分布特征、低频变化规律及其与太平洋年代际振荡(Pacific Decadal Oscillation, PDO)的关系, 并进一步探究了次表层盐度近年来的变化。结果显示: 1)南海次表层高盐水的位势密度主要介于24~26σθ, 受次表层气旋式环流所驱动, 盐度气候态空间分布北高南低, 以吕宋海峡处为起点, 呈逆时针自北向南逐渐降低。2)次表层盐度低频变化显著, 与PDO呈显著的正相关关系。当PDO处于正位相时, 吕宋海峡处西向平流输送加强, 次表层盐度升高; 当PDO处于负位相时, 吕宋海峡处西向平流输送减弱, 次表层盐度降低, 盐度的变化受到水平环流场的直接影响。3)近年来, 南海次表层盐度呈现先降低后升高再降低的趋势, 滞后PDO约10个月, 2006— 2014年初, 盐度呈下降趋势; 2014—2017年初, 盐度呈上升趋势, 且上升速率远大于先前下降的速率; 2017年后盐度再次逐渐降低。 相似文献
11.
Idealized numerical experiments with a depth level coordinate ocean circulation model (GFDL MOM3) have been conducted to investigate
the structure of interdecadal variability from thermally driven circulations. The model oceans are driven by steady surface
heat fluxes in the absence of surface wind stresses. Interdecadal variability is observed, with characteristics similar to
those reported in many previous studies. To explain the nature of the variability we propose a new mechanism based on two
local horizontal advective processes. This overcomes the limitations in previous theories based on the interplay between global
properties such as zonal and meridional temperature gradients and overturning. One of the two advective processes is a zonal
flow anomaly induced by a temperature anomaly along the northern wall through geostrophy southward of the temperature anomaly.
A cold (warm) anomaly along the northern wall produces a positive (negative) zonal flow anomaly that induces a warm (cold)
temperature anomaly by enhancing (weakening) warm advection from the western boundary along the path of the zonal flow anomaly.
The temperature and flow anomalies are transported toward the eastern boundary by the mean eastward zonal flow. When the positive
(negative) zonal flow anomaly that accompanies the warm (cold) temperature anomaly encounters the eastern wall, a downwelling
(upwelling) anomaly is produced. To dissipate the vorticity due to this downwelling (upwelling) anomaly, a northward (southward)
flow anomaly, which is another advective process governing the variability, is generated within a frictional boundary layer
next to the eastern wall. The northward (southward) flow anomaly circulates cyclonically along the perimeter of the basin
while enhancing (reducing) warm advection. So does the warm (cold) temperature anomaly carried to the eastern wall by the
mean zonal flow while pushing the cold (warm) anomaly that produced the positive (negative) zonal flow anomaly westward and
initiating the other half cycle of the variability. During the anomalous downwelling or upwelling, the available potential
energy stored in the anomalous density field is released to maintain the variability. Thus, neither barotropic nor baroclinic
instability supplies energy for the variability. The anomalous vertical velocity is stronger along the northern boundary and
the northern part of the eastern boundary. A shallow continental slope added along those boundaries prohibits the anomalous
vertical motion and weakens variability very effectively, while one along the western boundary does not. 相似文献
12.
盐度对变化2014年东北太平洋“暖泡”的作用 总被引:1,自引:0,他引:1
A significant strong, warm "Blob"(a large circular water body with a positive ocean temperature anomaly)appeared in the Northeast Pacific(NEP) in the boreal winter of 2013–2014, which induced many extreme climate events in the US and Canada. In this study, analyses of the temperature and salinity anomaly variations from the Array for Real-time Geostrophic Oceanography(Argo) data provided insights into the formation of the warm"Blob" over the NEP. The early negative salinity anomaly dominantly contributed to the shallower mixed layer depth(MLD) in the NEP during the period of 2012–2013. Then, the shallower mixed layer trapped more heat in the upper water column and resulted in a warmer sea surface temperature(SST), which enhanced the warm"Blob". The salinity variability contributed to approximately 60% of the shallowing MLD related to the warm"Blob". The salinity anomaly in the warm "Blob" region resulted from a combination of both local and nonlocal effects. The freshened water at the surface played a local role in the MLD anomaly. Interestingly, the MLD anomaly was more dependent on the local subsurface salinity anomaly in the 100–150 m depth range in the NEP.The salinity anomaly in the 50–100 m depth range may be linked to the anomaly in the 100–150 m depth range by vertical advection or mixing. The salinity anomaly in the 100–150 m depth range resulted from the eastward transportation of a subducted water mass that was freshened west of the dateline, which played a nonlocal role.The results suggest that the early salinity anomaly in the NEP related to the warm "Blob" may be a precursor signal of interannual and interdecadal variabilities. 相似文献
13.
北太平洋海表温度及各贡献因子的变化 总被引:2,自引:0,他引:2
采用1958年1月至2007年12月SODA海洋上层温度的月平均资料,基于海温变化方程和统计分析方法,分析了北太平洋海表面温度(SST)异常特征及各局地因子贡献比例的变化。结果表明,伴随着1976/1977风场最强中心位置的南北移动,形成了两个北太平洋SST年际-年代际变化的异常中心:一个是位于30°N附近的副热带海盆内区,SST异常主要受风应力强度的主导;一个是位于40°N附近的副热带和副极地环流交汇区,SST异常主要受风应力旋度的位置即风场位置的影响。在副热带海盆内区,最强降温发生在1978-1982年,SST异常的主要局地贡献因子为海表热通量和经向平流,二者所占比例和约为50%~60%,均为同相增温或降温作用,余项所占比例约为20%~50%。在副热带和副极地环流交汇区,海盆内区和西部边界区的SST异常的跃变时间同为1975年,但是内区的垂直混合项的跃变时间早于西部5年左右。SST异常的主要贡献因子为海表热通量和经向平流,但在1983-1988年海温强降温期间,经向平流项贡献大于海表热通量项的贡献。两个区域的垂直混合项均为降温贡献,虽然量值小却显示出很强的年代际变化信号。平流项中经向平流最大,垂直平流最小。 相似文献
14.
In this paper, effort is made to demonstrate the quality of high-resolution regional ocean circulation model in realistically simulating the circulation and variability properties of the northern Indian Ocean(10°S–25°N,45°–100°E) covering the Arabian Sea(AS) and Bay of Bengal(BoB). The model run using the open boundary conditions is carried out at 10 km horizontal resolution and highest vertical resolution of 2 m in the upper ocean.The surface and sub-surface structure of hydrographic variables(temperature and salinity) and currents is compared against the observations during 1998–2014(17 years). In particular, the seasonal variability of the sea surface temperature, sea surface salinity, and surface currents over the model domain is studied. The highresolution model's ability in correct estimation of the spatio-temporal mixed layer depth(MLD) variability of the AS and BoB is also shown. The lowest MLD values are observed during spring(March-April-May) and highest during winter(December-January-February) seasons. The maximum MLD in the AS(BoB) during December to February reaches 150 m (67 m). On the other hand, the minimum MLD in these regions during March-April-May becomes as low as 11–12 m. The influence of wind stress, net heat flux and freshwater flux on the seasonal variability of the MLD is discussed. The physical processes controlling the seasonal cycle of sea surface temperature are investigated by carrying out mixed layer heat budget analysis. It is found that air-sea fluxes play a dominant role in the seasonal evolution of sea surface temperature of the northern Indian Ocean and the contribution of horizontal advection, vertical entrainment and diffusion processes is small. The upper ocean zonal and meridional volume transport across different sections in the AS and BoB is also computed. The seasonal variability of the transports is studied in the context of monsoonal currents. 相似文献
15.
1992-2011年夏季南海西部离岸流区涡流相互作用特征 总被引:2,自引:1,他引:1
本文利用南海海洋再分析产品REDOS(Reanalysis Dataset of the South China Sea)和风场资料CCMP(Cross-Calibrated,Multi-Platform),从能量学角度探讨了1992-2011年夏季(6-9月)越南离岸流区域涡-流相互作用特征,并通过能量收支方程诊断评估了风应力、压力梯度、正压不稳定以及平流的相对贡献。以越南离岸流的强度作为分类标准,对1992-2011年划分为正异常年、负异常年和正常年。结果表明,在正异常年,涡动能EKE(Eddy Kinetic Energy)和涡势能EPE(Eddy available Potential Energy)极大值主要分布在越南离岸流附近;在负异常年,EKE极大值向南北两侧分散,EPE极大值向北延伸;在正常年,EKE和EPE的极值空间分布介于正负异常之间。斜压不稳定是EPE年际变化的主要因素,越南离岸流影响周围海域的速度和密度分布,是斜压不稳定的主要原因。而影响EKE年际变化的因素较为复杂,压力做功是最主要的影响因素,风应力做功和平流做功次之,正压不稳定最小,其中正压不稳定依赖于流速大小和由风应力旋度扰动引起的上层水平流速剪切。 相似文献
16.
Akira Nagano Kazuyuki Uehara Toshio Suga Yoshimi Kawai Hiroshi Ichikawa Meghan F. Cronin 《Journal of Oceanography》2014,70(4):389-403
Hydrographic data in the Kuroshio Extension (KE) region from 2008 to 2010 show large year-to-year variability in near-surface salinity, including a very large anomalous event in February 2010. During this event, the deep winter mixed layer in the southern KE region had higher salinity than had existed during the previous summer in September 2009. Our analysis shows that advection from the Philippine Sea along the western branch of the North Pacific subtropical gyre, taking approximately 9 months, resulted in this large salinity anomaly in February 2010 and contributes to the interannual salinity variability in the southern KE region. 相似文献
17.
Effects of interannual salinity variability on the dynamic height in the western equatorial Pacific as diagnosed by Argo 总被引:1,自引:1,他引:0
In this paper, interannual variations of the ocean dynamic height over the tropical Pacific are diagnosed using three-dimensional temperature and salinity fields from Argo profiles, with a focus on the... 相似文献
18.
印度洋上层海气相互作用对印度洋和太平洋气候系统有重要影响。目前针对印度洋气候态环流特征已有较为全面的研究,但针对印度洋环流的年际变化及其季节性差异的特征分析和具体作用机制,仍缺乏深入的研究。本文利用1979—2007年Simple Ocean Data Assimilation(SODA)再分析资料研究了赤道印度洋表层辐合辐散的年际变异及其季节依赖性。结果表明,以赤道为中心,印度洋上层异常海流,在经向上形成显著的辐合(辐散)现象,究其原因主要是赤道纬向风异常形成的Ekman流所导致。进一步分析表明,热带印度洋异常纬向风的成因与太平洋-印度洋的热力强迫过程作用有关,并且不同的热力强迫过程呈现出显著的季节差异性。此热力强迫过程,具体可分为3种类型:第一类是太平洋纬向海表热力差异的遥强迫作用,主要发生在冬末春初,热带太平洋的纬向热力差异通过调节Walker环流,在印度洋激发出一个异常的次级环流,对应的大气低层形成纬向风异常;第二类是东-西印度洋海表热力差异的局地强迫作用导致的局地环流,使赤道印度洋上空形成纬向风异常,此过程在春末夏初较为显著;第三类是太平洋-印度洋热力差协同作用的结果,使赤道印度洋盛行异常的纬向风,此过程在秋季起主导作用。 相似文献
19.
Spatial and temporal structure of Tropical Pacific interannual variability in 20th century coupled simulations 总被引:1,自引:0,他引:1
Tropical Pacific interannual variability is examined in nine state-of-the-art coupled climate models, and compared with observations and ocean analyses data sets, the primary focus being on the spatial structure and spectral characteristics of El Niño-Southern Oscillation (ENSO). The spatial patterns of interannual sea surface temperature (SST) anomalies from the coupled models are characterized by maximum variations displaced from the coast of South America, and generally extending too far west with respect to observations. Thermocline variability is characterized by dominant modes that are qualitatively similar in all the models, and consistent with the “recharge oscillator” paradigm for ENSO. The meridional scale of the thermocline depth anomalies is generally narrower than observed, a result that can be related to the pattern of zonal wind stress perturbations in the central-western equatorial Pacific. The wind stress response to eastern equatorial Pacific SST anomalies in the models is narrower and displaced further west than observed. The meridional scale of the wind stress can affect the amount of warm water involved in the recharge/discharge of the equatorial thermocline, while the longitudinal location of the wind stress anomalies can influence the advection of the mean zonal temperature gradient by the anomalous zonal currents, a process that may favor the growth and longer duration of ENSO events when the wind stress perturbations are displaced eastwards. Thus, both discrepancies of the wind stress anomaly patterns in the coupled models with respect to observations (narrow meridional extent, and westward displacement along the equator) may be responsible for the ENSO timescale being shorter in the models than in observations. The examination of the leading advective processes in the SST tendency equation indicates that vertical advection of temperature anomalies tends to favor ENSO growth in all the CGCMs, but at a smaller rate than in observations. In some models it can also promote a phase transition. Longer periods tend to be associated with thermocline and advective feedbacks that are in phase with the SST anomalies, while advective tendencies that lead the SST anomalies by a quarter cycle favor ENSO transitions, thus leading to a shorter period. 相似文献