共查询到20条相似文献,搜索用时 31 毫秒
1.
The high-resolution Bay of Bengal circulation modeling in the region [80E–95E; 5N–22N] is performed with a horizontal resolution of 10 km and the highest vertical resolution of 5 m near the surface. The intercomparison experiments, with ocean model forced with the near-surface (1) National Centers for Environmental Prediction (NCEP) reanalysis winds and (2) blended seawinds data (a combination of remotely sensed scatterometer and in situ observations) are carried out for a period of 17 years during 1998–2014. The seasonal variability of the realistically simulated surface hydrographic (temperature and salinity) and circulation (currents) variables from both the experiments is compared and contrasted with the observational data. The mixed layer depth seasonal variability of the region is also studied. The mesoscale features of currents at 50 and 100 m are also studied. The volume transport across different sections in the Bay of Bengal is computed and its relation with summer monsoon rainfall is investigated. The results suggest that there is no real advantage of using high-resolution blended seawinds over the much coarser NCEP reanalysis winds. 相似文献
2.
To date, coral proxy studies have proved largely unsuccessful in reconstructing temporal variability of the Indian monsoon
system in the NW Indian Ocean. In a recent publication in this journal, Storz and Gischler demonstrated that extension rates
in corals can be used to fill this gap. Those authors found a link between decadal and interannual variations of the SW monsoon
current velocities and Porites lutea extension rates in the lagoon of Rasdhoo Atoll (4°N/73°W) in the central Maldives for the period 1917–2007. This sister paper
shows that this extension-rate record can be used to reconstruct decadal variations of summer monsoon rainfall over peninsular
India and adjacent areas. The amount of monsoon rainfall and current velocities during summer are both affected by the strength
of the Indian monsoon system. Assessments of coral extension rates and the mean May–September All India Monsoon Rainfall index,
a measure of monsoon strength over the Indian subcontinent, revealed a significant spectral coherence within periods of 18–19
and 6–7 years. Almost 92% of variance is shared between both time series in the former band, and 85% in the latter. A correlation
between the 5-year running mean extension rate and rainfall records from the Western Ghats (grid of 73–76°E/13–15°N) is significant
especially for 1958–2006 (r = −0.82, p < 0.05). These findings imply that coral growth characteristics can serve as a new marine archive to reconstruct past variations
of the Indian monsoon system on interannual to decadal timescales. 相似文献
3.
赤道印度洋海温偶极子的气候影响及数值模拟研究 总被引:5,自引:0,他引:5
在分析研究印度洋海温变化的基本特征,尤其是在分析赤道印度洋海温偶极子及其影响的基础上,利用IAP9L大气环流模式模拟研究了赤道印度洋海温偶极子异常对亚洲季风区气候变化的影响.其结果表明,印度洋、亚洲南部和东部地区的流场和降水都对印度洋海温异常的强迫作用比较敏感.正位相印度洋偶极子的作用使得赤道东印度洋-印度次大陆南部-阿拉伯海一带出现距平东风,孟加拉湾-中南半岛出现异常反气旋性环流,从而对减少印度南部和中南半岛南部、印度尼西亚地区的夏季降水,以及增加中国南部和东非的夏季降水有十分重要的作用.与此相反,负位相印度洋偶极子的作用将使赤道东印度洋附近出现西风异常,孟加拉湾-中南半岛存在异常气旋性环流,从而使印度次大陆和中南半岛南部、印度尼西亚地区的降水增加,使中国西部和孟加拉湾的降水减少.数值模拟结果与资料分析相互映证,切实地揭示了印度洋海温偶极子对亚洲季风区的气候变化有重要影响. 相似文献
4.
采用EOF(Emprical Orthogonal Function)、小波分析和交叉小波分析等方法研究了福建省汛期降水的不同空间分布型在不同的时间尺度下与西北太平洋夏季风、印度洋夏季风的关系.结果表明:福建汛期降水空间分布以全省一致型和东南—西北反相型两种模态为主;西北太平洋夏季风主要影响福建整个汛期降水总量的多寡,当西太平洋夏季风较强(弱)时,福建整个汛期全省降水偏多(少);而印度洋夏季风则主要影响福建汛期降水量东南-西北向差异,即ISM强(弱),福建东南-西北部降水差异增大(减小). 相似文献
5.
基于TRMM观测的亚洲——太平洋三个季风区的降水结构特征 总被引:1,自引:0,他引:1
The three-dimensional structure of precipitation on a seasonal scale in the Asian-Pacific's three monsoon regions is investigated based on the tropical rainfall measurement mission (TRMM) data. The results show that: (1) The maximum seasonal variation of the relative proportional difference of convective precipitation and stratiform rain occurs in the East Asian monsoon region, the second occurs in the Indian monsoon region, and the minimum is in the northwest Pacific monsoon region. In both the northwest Pacific mon soon region and the Indian monsoon region, the convective rain is proportionately larger than stratiform rain in all four seasons. (2) Cloud ice reaches its maximum at around 9 km. Cloud water's maximum range is between 3 and 4 km. The large value area of precipitation ice is mainly between 4 and 9 km. The precipi tation water particle is concentrated mostly below 4 km. The largest content is from the ground to 2 km. (3) The most remarkable variance of the content of cloud ice in the Indian monsoon region occurs from spring to winter, and the content of cloud water in the northwest Pacific is always higher than that in the other two regions. (4) The latent heat profile has a similar double-peak structure. The first peak is at 4 km and the second peak is at 2 km. In autumn and winter, the latent heat is higher in the northwest Pacific than in other two regions. In all three regions, the release of the latent heat is higher in summer and autumn than in spring and winter. 相似文献
6.
Interannual variability of upwelling indices in the Southeastern Arabian Sea: A satellite based study 总被引:2,自引:0,他引:2
Chiranjivi Jayaram Neethu Chacko K. Ajith Joseph A. N. Balchand 《Ocean Science Journal》2010,45(1):27-40
Increase in sea surface temperature with global warming has an impact on coastal upwelling. Past two decades (1988 to 2007) of satellite observed sea surface temperatures and space borne scatterometer measured winds have provided an insight into the dynamics of coastal upwelling in the southeastern Arabian Sea, in the global warming scenario. These high resolution data products have shown inconsistent variability with a rapid rise in sea surface temperature between 1992 and 1998 and again from 2004 to 2007. The upwelling indices derived from both sea surface temperature and wind have shown that there is an increase in the intensity of upwelling during the period 1998 to 2004 than the previous decade. These indices have been modulated by the extreme climatic events like El-Nino and Indian Ocean Dipole that happened during 1991–92 and 1997–98. A considerable drop in the intensity of upwelling was observed concurrent with these events. Apart from the impact of global warming on the upwelling, the present study also provides an insight into spatial variability of upwelling along the coast. Noticeable fact is that the intensity of offshore Ekman transport off 8°N during the winter monsoon is as high as that during the usual upwelling season in summer monsoon. A drop in the meridional wind speed during the years 2005, 2006 and 2007 has resulted in extreme decrease in upwelling though the zonal wind and the total wind magnitude are a notch higher than the previous years. This decrease in upwelling strength has resulted in reduced productivity too. 相似文献
7.
用MM5区域气候模式对1994年6月东亚季风进行了数值模拟。模式模拟的月平均环流和降水与实况相接近。1994年6月东亚季风活动十分异常,中国东南部的西南季风、西太平洋副热带高压、南亚高压都出现了两次突变性的北跳,对此模式均做出了较好的模拟 相似文献
8.
Vinu Valsala 《Journal of Oceanography》2009,65(6):803-816
The spreading pathways of the Somali and Arabian coastal upwelled waters in the northern Indian Ocean are identified from
an ocean re-analysis data set of a single year using numerical passive tracers in a transport model. The Somali and Arabian
coastal upwelled waters are found to have entirely different spreading pathways in the northern Indian ocean. The former circulates
anticyclonically, is mixed vertically, and is advected to the eastern Indian Ocean along the north equatorial region; while
the later intrudes into the northern Arabian Sea, circulates anticyclonically and is advected to the south in the central
Arabian Sea and then to the eastern Indian Ocean. The seasonal surface mixing by strong monsoon winds and sheared currents
due to dominant eddies of the Somali region are found responsible for mixing 25% of Somali upwelled water with the subsurface
and affecting the resultant pathways. The effect of mixing is, however, found negligible in the case of Arabian coastal upwelled
water pathways. The seasonal reversal of circulation and eddy dominance during the southwest monsoon cause the Somali upwelled
water to spread over the northern Indian Ocean faster than the simultaneously upwelled Arabian coastal water. 相似文献
9.
利用美国国家环境预报中心和气象研究中心的42年模式再分析资料,采用合成分析的方法,考察了南海夏季风爆发时期环流季节变化的特征.研究发现:尽管采用不同指标确定的南海夏季风爆发时间在有的年份差别很大,但各种不同指标对应的南海夏季风爆发时期大气环流的变化具有某些共同的特征.通过对各种指标确定夏季风爆发时间一致年份的大气环流特征分析表明,延伸到南海北岸附近地区的海上锋区对流加热和孟加拉湾北部陆地上的对流加热、沿东亚近海向西太平洋推进的冷空气是控制南海夏季风爆发的主要因素.对南海夏季风爆发早与爆发晚的年份的合成环流特征进一步表明:爆发早的年份,影响东亚附近海区的冷空气势力和南海南部的对流活动相对强,而爆发晚的年份,冷空气和南海南部的对流活动的影响要相对弱的多.日本本岛南部黑潮海区因冷空气激发的对流活动对南海夏季风的爆发也有重要的影响. 相似文献
10.
南海夏季风暴发过程的低频特征 总被引:7,自引:2,他引:5
应用1979~1996年共18a的NOAA卫星OLR资料及NCEP/NCAR再分析850hPa风场资料,分析了夏季南海地区及南海季风暴发过程的某些低频特征。认为北半球夏季南海地区的低频活动较活跃,并且具有明显的年际变化,这种年际变化同南海季风的暴发时间有联系。南海地区的低频振荡在南海季风暴发后增强。通过对18a 及K*的时段叠加合成图的分析,发现南海夏季风的暴发同赤道印度洋低频振荡的东传及西太平洋低频扰动西传有密切联系,南海夏季风暴发期间南海地区将印度洋与西太平洋之间的低频活动联系在一起。 相似文献
11.
基于近40 a NCEP/NCAR再分析月平均高度场、风场、涡度场、垂直速度场以及NOAA重构的海面温度(sea surface temperature,SST)资料和美国联合台风预警中心(Joint Typhoon Warning Center,JTWC)热带气旋最佳路径资料,利用合成分析方法,研究了前期春季及同期夏季印度洋海面温度同夏季西北太平洋台风活动的关系。结果表明:1)前期春季印度洋海温异常(sea surface temperature anomaly,SSTA)尤其是关键区位于赤道偏北印度洋和西南印度洋地区对西北太平洋台风活动具有显著的影响,春季印度洋海温异常偏暖年,后期夏季,110°~180°E的经向垂直环流表现为异常下沉气流,对应风场的低层低频风辐散、高层辐合的形势,这种环流形势使得低层水汽无法向上输送,对流层中层水汽异常偏少,纬向风垂直切变偏大,从而夏季西北太平洋台风频数偏少、强度偏弱,而异常偏冷年份则正好相反。2)春季印度洋异常暖年,西北太平洋副热带高压加强、西伸;而春季印度洋异常冷年,后期夏季西北太平洋副热带高压减弱、东退,这可能是引起夏季西北太平洋台风变化的另一原因。 相似文献
12.
回顾了对南印度洋副热带海气相互作用的研究,总结了南印度洋偶极子事件背景下的气候变化。印度洋海表温度的方差表明南印度洋是整个印度洋海温变率最强的区域,年际海温变化最显著的特征就是海温呈现西南东北向的偶极子型分布,被称为南印度洋偶极子(Southern Indian Ocean Dipole, SIOD)。南印度洋海温偶极子的形成主要是受大尺度大气环流调整的影响。南印度洋副热带反气旋环流异常引起了印度洋热带东风异常和副热带西风异常的变化,影响了潜热通量、上升流和Ekman热输送,进而引起了海温变化。SIOD对热带和热带外大气环流也有影响,尤其会影响亚洲夏季风降水异常,例如我国的降水异常和南印度洋偶极子海温异常具有显著相关关系。此外,SIOD模态所引起的经向环流异常与南海、菲律宾地区的反气旋环流异常也有紧密联系。 相似文献
13.
南印度洋SST与南亚季风环流年代际变化的研究 总被引:2,自引:0,他引:2
利用美国NCEP全球大气再分析资料和JONES全球海表面温度异常(SSTA)资料,分析了南印度洋SSTA和南亚季风环流年代际变化的特征。研究发现,无论是南印度洋副热带海水辐合区的SST还是赤道以北非洲西海岸附近上升运动海区的SST的长期变化趋势,除了准3-5年的变化以外,还存在着明显的年代际的变化。对于全球最显著南亚季风环流的分析表明,南亚季风环流也存在明显的年代际时间尺度的变化。与南太平洋SST的年代际变化相比,南印度洋SST的变化周期要相对短一些。通过分析南半球冷空气年代际活动的特征发现,冷空气与南印度洋SST年代际时间尺度的变化具有密切的联系。 相似文献
14.
V.V. Gopalakrishna F. Durand K. Nisha M. Lengaigne T.P. Boyer J. Costa R.R. Rao M. Ravichandran S. Amrithash L. John K. Girish C. Ravichandran V. Suneel 《Deep Sea Research Part I: Oceanographic Research Papers》2010,57(6):739-754
The southeastern Arabian Sea (SEAS), located in the Indian Ocean warm pool, is a key-region of the regional climate system. It is suspected to play an important role in the dynamics of the Asian summer monsoon system. The present study reports the salient features derived from a newly harvested observational dataset consisting of repeated fortnightly XBT transects in the SEAS over the period 2002–2008. The fortnightly resolution of such a multi-year record duration is unprecedented in this part of the world ocean and provides a unique opportunity to examine the observed variability of the near-surface thermal structure over a wide spectrum, from intra-seasonal to interannual timescales. We find that most of the variability is trapped in the thermocline, taking the form of upwelling and downwelling motions of the thermal stratification. The seasonal variations are consistent with past studies and confirm the role of the monsoonal wind forcing through linear baroclinic waves (coastally-trapped Kelvin and planetary Rossby waves). Sub-seasonal variability takes the form of anomalous events lasting a few weeks to a few months and occurs at two preferred timescales: in the 30–110 day band, within the frequency domain of the Madden–Julian oscillation and in the 120–180 day band. While this sub-seasonal variability appears fairly barotropic in the offshore region, the sign of the anomaly in the upper thermocline is opposite to that in its lower part on many occasions along the coast. Our dataset also reveals relatively large interannual temperature variations of about 1 °C from 50 to 200 m depth that reflect a considerable year-to-year variability of the magnitude of both upwelling and downwelling events. This study clearly demonstrates the necessity for sustained long-term temperature measurements in the SEAS. 相似文献
15.
新生代以来澳大利亚板块向北漂移了~20°,气候也随之发生了明显改变,即其北部逐渐进入了热带辐合带的影响范围,与亚欧大陆间的联系越来越紧密。上新世时印度尼西亚贯穿流的流通性受到限制,这可能直接促成了澳大利亚季风的形成。海洋沉积记录显示,澳大利亚气候的季节性特征最早出现于~3.5 Ma,而现代意义上的澳大利亚季风则形成于~2.4 Ma。第四纪阶段的澳大利亚季风表现出明显的轨道周期:冰期(间冰期)时夏季风减弱(加强),其演化主要受控于北半球日射量、东亚冬季风的跨赤道作用、表层海水温度与海平面高度变化。在更短的时间尺度上,末次冰期以来的澳大利亚季风则具有与北半球高纬度地区典型气候事件相似的千年周期,大致表现为:北半球的丹斯伽阿德—厄施格尔(Dansgaard/Oeschger)暖期对应着澳大利亚夏季风强度的减弱,而北半球的海因里希(Heinrich stadials)与新仙女木(Younger Dryas)冷事件时澳大利亚夏季风增强。但马来群岛不同地区的上述古气候记录之间存在差异,这可能与区域性因素的影响有关。季风降水的千年尺度变化与热带辐合带的位置密切相关,且其相位变化与同纬度的非洲和南美洲古季风截然不同,明显响应了北半球日射量,这可能与亚洲季风系统的跨赤道作用有关。末次冰期古生产力研究表明,在班达海与澳大利亚西北沿海,澳大利亚季风可以通过影响洋流模式、陆表降水与径流,来控制陆源物质向海洋的输送、海水结构的稳定性以及表层海水过程,进而影响海洋生物生产力。 相似文献
16.
The seasonal variability of sonic layer depth (SLD) in the central Arabian Sea (CAS) (0 to 25°N and 62-66°E) was studied using
the temperature and salinity (T/S) profiles from Argo floats for the years 2002–2006. The atmospheric forcing responsible
for the observed changes was explored using the meteorological data from NCEP/NCAR and Quickscat winds. SLD was obtained from
sound velocity profiles computed from T/S data. Net heat flux and wind forcing regulated SLD in the CAS. Up-welling and down-welling
(Ekman dynamics) associated with the Findlater Jet controlled SLD during the summer monsoon. While in winter monsoon, cooling
and convective mixing regulated SLD in the study region. Weak winds, high insolation and positive net heat flux lead to the
formation of thin, warm and stratified sonic layer during pre and post summer monsoon periods, respectively. 相似文献
17.
Using observations and numerical simulations, this study examines the intraseasonal variability of the surface zonal current(u ISV) over the equatorial Indian Ocean, highlighting the seasonal and spatial differences, and the causes of the differences. Large-amplitude u ISV occurs in the eastern basin at around 80°–90°E and near the western boundary at 45°–55°E. In the eastern basin, the u ISV is mainly caused by the atmospheric intraseasonal oscillations(ISOs), which explains 91% of the standard... 相似文献
18.
华北地区夏季降雨量与南海海温长期变化的关系 总被引:6,自引:0,他引:6
比较了华北地区7个站与17个站1951-1997年夏季(6,7,8月)降雨量与气候随时间的变化特征,并对其成因作了探讨。结果表明,用北京、天津、邢台、烟台、郑州、太原和济南等7个站可代表该地区夏季降雨量与气候的多尺度变化特征,过去47a该地区依次经历了湿凉、湿热、湿凉、干热、湿热几个时期,降雨量的长期变化与南海前冬(1-2月)海温成负相关。前冬南海海温偏高,意味着初夏南海地区大气对流低频振动偏弱,南海夏季风爆发较晚,西南季风较弱,夏季西太平洋副高位置偏南,华北地区大气低层北风加强,华北地区夏季少雨,前冬南海海温偏低时情况则相反,考虑冬季(1-2月)南海南温和7-8月西太平洋副高脊线位置(纬度)的影响用均生函数建模,试验结果与用子波变换重构方法考虑华北地区夏季降雨量的变化趋势比较,二者相吻合,预测试验结果与过去3a的实况基本一致。 相似文献
19.
上层经向翻转环流(shallow meridional overturning circulation, SMOC)主导热带-副热带上层海洋水体交换,对海洋物质输运和热量交换具有重要意义。基于7套海洋再分析数据产品,本文主要探讨了印度洋SMOC的冬夏季节变化及其差异的原因。结果显示,印度洋SMOC主要由南半球副热带环流圈(southern subtropical cell, SSTC)和跨赤道环流(cross-equatorial cell, CEC)组成,并且具有显著的季节差异。夏季风期间, SSTC和CEC均为表层南向输运,表层以下北向输运的逆时针环流结构。冬季风盛行时, SSTC仍维持逆时针结构,但环流中心南移且深度加深,强度弱于夏季;然而, CEC却转向为表层北向输运,表层以下向南输运的顺时针环流结构,其环流中心位置与夏季接近,环流强度与夏季相当。这种印度洋SMOC冬夏结构差异究其原因主要由风生环流主导, CEC冬夏季节环流方向反转是北印度洋冬夏季风转向的结果,而南印度洋信风的季节性位移和强度变化是SSTC强度和位置季节差异的主要原因。 相似文献
20.
热带印度洋上层水温的年循环特征 总被引:1,自引:0,他引:1
通过分析多年气候月平均的Levitus水温资料,结合多年气候月平均海表面风场资料以及观测的热带印度洋上层海流的分布状况,探讨热带印度洋上层水温的时空分布特征,剖析了热带印度洋混合层深度及印度洋暖水的季节变化规律。分析表明:热带印度洋的海表面温度低值区始终位于大洋的南部,而高值区呈现明显的季节变化,冬季位于赤道附近,在夏季则处于大洋的东北部;在热带印度洋的中西部、赤道偏南海域的次表层终年存在一冷心结构;热带印度洋表面风场的季节变化是影响该海域混合层深度季节性变化的主要因素;印度洋暖水在冬、春季范围较大,与西太平洋暖池相连,而在夏、秋季范围较小,并与西太平洋暖池分开。 相似文献