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21.
冬季北太平洋西部上层海洋的热量输送 总被引:1,自引:2,他引:1
用海气界面净热量收支和1950-1979年表层水温资料,计算了冬季北太平洋西部上层海洋热通量散度场,指出冬季北太平洋西部黑潮将大量低纬暖水输送到中高纬度海域,在30-35°N最大;亲潮将极地冷水沿千岛群岛向南输送,在45-50°N最大;两者在40°N附近相遇,混合减弱后沿纬向东传。同时用EOF分析方法对热通量散度距平场分型,前3个主要型分别为:黑潮亲潮偶合型、北太平洋海流型和冷平流优势型。最后还揭示了第一主要型与北太平洋副热带高压之间有意义的相关关系。 相似文献
22.
东海带鱼(Trichiurus haumela)渔获量与邻近海域水文环境变化的关系 总被引:6,自引:1,他引:6
利用35年的东海区带鱼年渔获量资料与长江径流及东海温、盐断面资料、SST和黑潮流量资料,分析了东海渔获量年际变化与海洋环境的关系。结果表明,东海渔获量与长江径流和黑潮暖流的变化有密切的关系,长江径流量大时,东海渔获量高;反之,则低。1960年以来东海区渔获量的4次长期波动与长江径流的年代际变化基本一致。东海渔获量的丰、欠与黑潮(流量)的强、弱呈反位相变化,秋季的黑潮流量与渔获量的变化关系尤其显著;黑潮强(弱)时,东海渔获量低(高)。受长江径流和黑潮的影响,渔获量与盐度的高相关区夏季位于长江口区,秋季则位于黑潮左侧的盐锋内;东海渔获量高(低)分别与区域内盐度的低(高)变化相一致。东海区渔获量与不同季节SST变化的高相关区(即渔场区)关系密切,冬季(2月)位于东海北部的大沙渔场,春(5月)、夏季(8月)位于长江口舟山渔场,秋末初冬(12月)位于舟山及陆架暖流区,渔获量丰年与渔场区SST正异常相对应。 相似文献
23.
Analysis using historical data on the phosphate sources in Changjiang (Yangtze River) estuary show that phosphate was supplied equally from the east, south, west and north of the estuary. These sources include the Changjiang River, the Taiwan Warm Current (TWC), a cyclone-type eddy, and the 32°N Upwelling, supplying different phosphates in different times, ways and intensities. The magnitude of their supplying phosphate concentration was related with the size in the order of the Changjiang River 〈 the TWC 〈 the 32°N Upwelling 〈 the cyclone-type eddy, and the duration of the supplying was: the Changjiang River 〉 the TWC 〉 the cyclone-type eddy 〉 the 32°N Upwelling. The four sources supplied a great deal of phosphate so that the phosphate concentration in the estuary was kept above 0.2 pmol/L in previous years, satisfying the phytoplankton growth. The horizontal and vertical distribution of the phosphate concentration showed that near shallow marine areas at 122°E/31°N, the TWC in low nutrient concentration became an upwelling through sea bottom and brought up nutrients from sea bottom to marine surface. In addition, horizontal distribution of phosphate concentration was consistent with that of algae: Rhizosolenia robusta, Rhizosolenia calcaravis and Skeletonema, which showed that no matter during high water or low water of Changjiang River, these species brought by the TWC became predominant species. Therefore, the authors believe that the TWC flowed from south to north along the coast and played a role in deflecting the Changjiang River flow from the southern side. 相似文献
24.
南海夏季风爆发与热带海洋海温和大气环流异常变化关系的研究 总被引:12,自引:0,他引:12
用合成和相关分析方法及SVD技术研究了南海夏季风爆发早、晚年份4~6月季风建立时期季风环流的异常及其与热带太平洋-印度洋海温的关系。结果表明,南海夏季风爆发与热带大气环流和海温变异密切相关。(1)当热带中、东太平洋—印度洋(主要在西南部)及南海海温低(高),西太平洋—澳洲邻近海域海温高(低)时,南海夏季风爆发早(晚)。不同区域海温对季风的影响有明显的季节差异,印度洋主要为晚春至初夏(4~6月),南海为5~6月,而热带太平洋从前冬一直持续到夏季。(2)不同的海温异常产生不同的季风环流型,南海夏季风爆发早、晚年大气环流的异常变化基本相反。南海夏季风的活动主要受印度季风环流变化的影响,与前期冬春季西太副高的强弱及位置变化密切相关。西太副高弱时,南海夏季风爆发早;反之,爆发晚。(3)热带太平洋—印度洋海温异常引起季风环流和Walker环流的异常变化可能是影响南海夏季风爆发早、晚的物理过程。 相似文献
25.
The South China Sea warm pool interacts vigorously with the summer monsoon which is active
in the region. However, there has not been a definition concerning the former warm pool which is as specific as
that for the latter. The seasonal and inter-annual variability of the South China Sea warm pool and its relations
to the South China Sea monsoon onset were analyzed using Levitus and NCEP/NCAR OISST data. The results
show that, the seasonal variability of the South China Sea warm pool is obvious, which is weak in winter, develops
rapidly in spring, becomes strong and extensive in summer and early autumn, and quickly decays from
mid-autumn. The South China Sea warm pool is 55 m in thickness in the strongest period and its axis is oriented
from southwest to northeast with the main section locating along the western offshore steep slope of
northern Kalimantan-Palawan Island. For the warm pools in the South China Sea, west Pacific and Indian
Ocean, the oscillation, which is within the same large scale air-sea coupling system, is periodic around 5 years.
There are additional oscillations of about 2.5 years and simultaneous inter-annual variations for the latter two
warm pools. The intensity of the South China Sea warm pool varies by a lag of about 5 months as compared to
the west Pacific one. The result also indicates that the inter-annual variation of the intensity index is closely
related with the onset time of the South China Sea monsoon. When the former is persistently warmer (colder) in
preceding winter and spring, the monsoon in the South China Sea usually sets in on a later (earlier) date in
early summer. The relation is associated with the activity of the high pressure over the sea in early summer. An
oceanic background is given for the prediction of the South China Sea summer monsoon, though the mechanism
through which the warm pool and eventually the monsoon are affected remains unclear. 相似文献
26.
27.
Long-term variabilities of thermodynamic structure of the East China Sea Cold Eddy in summer 总被引:6,自引:0,他引:6
Based on more than 30 years observed sectional temperature data since the 1960s, and compared with multi-year wind and Changjiang (Yangtze) River discharge data, spatial-temporal variations of the East China Sea Cold Eddy (ECSCE) in summer was analyzed in relationship to ocean circulation and local atmospheric circulation. Empirical Orthogonal Function (EOF) and Singular Value Decomposition (SVD) analyseswere applied to this study. The results show that: l) The ECSCE in summer possesses significant interannual variabilities, which are directly associated with oceanic and atmospheric circulation anomaly. Main fluctuations demonstrate their falling in basically with E1 Nino events (interannual) and interdecadal variability. 2) The ECSCE in summer is closely related to the variation of the Yellow Sea Warm Current (YSWC) and the Changjiang River discharge. The stronger the YSWC, the more intensive the ECSCE with its center shifting westward,and vice versa. However, a negative correlation between the Changjiang River discharge and the ECSCE strength is shown. The ECSCE was strengthened after the abrupt global climate change affected by the interdecadal variation of the YSWC. 3) SVD analysis suggested a high correlation between the variation of the ECSCE in summer and the anomalous cyclonic atmospheric circulation over the ECS. Intensification of the cyclonic wind strengthens the ECSCE, and vice versa. 4) The cyclonic atmospheric circulation has dominant influence on the interannual variation of the ECSCE, and the influence of the ocean circulation takes the second in. The ECSCE was usually stronger in E1 Nifio years affected by strong cyclonic circulation in the atmosphere. The variation in strength of the ECSCE resulted from the joint effect of both oceanic and atmospheric circulation. 相似文献
28.
热带太平洋次表层海温异常年代际变率及其对中国气候异常的影响 总被引:4,自引:0,他引:4
利用近50年月平均的SODA海洋同化资料和NCEP大气再分析资料,研究了热带太平洋次表层海温异常(SOTA)年代际变率主要分布型以及与之相关的亚洲-北太平洋-北美地区上空异常大气环流场,并揭示了类ENSO模态与中国气候异常之间的联系.得到主要结果:(1)热带太平洋SOTA年代际变率有两种类ENSO模态.第一模为类ENSO事件成熟期热带太平洋年代际SOTA状态;第二模为类ENSO过渡期热带太平洋年代际SOTA状态.二者组合构成类ENSO事件40年左右及其背景下13年左右的周期振荡.(2)类ENSO事件对亚洲-北太平洋-北美上空中高纬和副热带大气系统年代际变化具有重要影响.类El Ni(n)o成熟期间冬季,中高纬地区大气环流经向型发展,贝加尔湖高压脊加强,西太平洋副高偏强、位置偏西,蒙古高原为较强的异常反气旋环流.类El Ni(n)o衰退期(类La Ni(n)a发展期)夏季,贝加尔湖低压槽加深,乌拉尔山高压脊加强,西太平洋副高偏弱,新疆-河套地区为较强的异常反气旋环流距平.类La Ni(n)a事件时相反.(3)热带太平洋类ENSO事件通过影响中高纬和副热带大气系统,造成中国北部地区上空南风距平的年代际变化,进而导致东亚季风和中国气候异常.类El Ni(n)o事件成熟期,中国北部地区上空多异常偏北风,东亚季风弱,华北少雨,长江中、下游多雨;类El Ni(n)o衰退(类La Ni(n)a发展)期,中国北部地区上空亦为异常偏北气流,东亚季风较弱,华北少雨.中国气候异常型主要取决于类ENSO第一模态,而第二模态主要视位相异同来加强或减弱第一模态.两个类ENSO模态的共同作用导致1978年前后中国气候跃变和华北地区持续20余年的干旱.近期类ENSO模的振荡从1998年左右开始转为类La Ni(n)a模态,大致在2018年左右结束.在此期间,华北降水有望增加,长江中、下游降水可能减少. 相似文献
29.
ENSO cycle and climate anomaly in China 总被引:2,自引:0,他引:2
The inter-annual variability of the tropical Pacific Subsurface Ocean Temperature Anomaly (SOTA) and the associated anomalous atmospheric circulation over the Asian North Pacific during the El Ni o-Southern Oscillation (ENSO) were investigated using National Centers for Environmental Prediction/ National Center for Atmospheric Research (NCEP/NCAR) atmospheric reanalysis data and simple ocean data simulation (SODA). The relationship between the ENSO and the climate of China was revealed. The main results indicated the following: 1) there are two ENSO modes acting on the subsurface tropical Pacific. The first mode is related to the mature phase of ENSO, which mainly appears during winter. The second mode is associated with a transition stage of the ENSO developing or decaying, which mainly occurs during summer; 2) during the mature phase of El Ni o, the meridionality of the atmosphere in the mid-high latitude increases, the Aleutian low and high pressure ridge over Lake Baikal strengthens, northerly winds prevail in northern China, and precipitation in northern China decreases significantly. The ridge of the Ural High strengthens during the decaying phase of El Ni o, as atmospheric circulation is sustained during winter, and the northerly wind anomaly appears in northern China during summer. Due to the ascending branch of the Walker circulation over the western Pacific, the western Pacific Subtropical High becomes weaker, and south-southeasterly winds prevail over southern China. As a result, less rainfall occurs over northern China and more rainfall over the Changjiang River basin and the southwestern and eastern region of Inner Mongolia. The flood disaster that occurred south of Changjiang River can be attributed to this. The La Ni a event causes an opposite, but weaker effect; 3) the ENSO cycle can influence climate anomalies within China via zonal and meridional heat transport. This is known as the "atmospheric-bridge", where the energy anomaly within the tropical Pacific transfers to the mid-high latitude in the northern Pacific through Hadley cells and Rossby waves, and to the western Pacific-eastern Indian Ocean through Walker circulation. This research also discusses the special air-sea boundary processes during the ENSO events in the tropical Pacific, and indicates that the influence of the subsurface water of the tropical Pacific on the atmospheric circulation may be realized through the sea surface temperature anomalies of the mixed water, which contact the atmosphere and transfer the anomalous heat and moisture to the atmosphere directly. Moreover, the reason for the heavy flood within the Changjiang River during the summer of 1998 is reviewed in this paper. 相似文献
30.
The seasonal generation and evolution of eddies in the region of the North Pacific Subtropical Countercurrent remain poorly
understood due to the scarcity of available data. We used TOPEX/POSEIDON altimetry data from 1992 to 2007 to study the eddy
field in this zone. We found that velocity shear between this region and the neighboring North Equatorial Current contributes
greatly to the eddy generation. Furthermore, the eddy kinetic energy level (EKE) shows an annual cycle, maximum in April/May
and minimum in December/January. Analyses of the temporal and spatial distributions of the eddy field revealed clearly that
the velocity shear closely related to baroclinic instability processes. The eddy field seems to be more zonal than meridional,
and the energy containing length scale shows a surprising lag of 2–3 months in comparison with the 1-D and 2-D EKE level.
A similar phenomenon is observed in individual eddies in this zone. The results show that in this eddy field band, the velocity
shear may drive the EKE level change so that the eddy field takes another 2–3 months to grow and interact to reach a relatively
stable state. This explains the seasonal evolution of identifiable eddies. 相似文献