黄海冷水团的环流结构

运用定性分析和数值模拟，对黄海冷水团的环流结构进行了探讨，结果表明黄海冷水团的垂向环流结构为双环结构：跃层以上区为中心上升，边缘下降的弱环流;跃层以下区为中心下降，边缘上升的强环流；在冷水团的中心区域，流动很弱，且无穿越温跃层的垂向流动。同时也对以往有关黄海冷水团垂向环流结构的工作进行了讨论。     

夏季南黄海深层冷水团内部的水文结构

在整个黄海水域，夏季存在着范围广阔的深层冷水块。习惯上根据地域分布的不同，把地处北黄海的冷水块叫“北黄海冷水团”，地处南黄海的叫“南黄海冷水团”这两冷水块连成一体通称“黄海冷水团”。赫崇本是我国最早分析黄海冷水团的基本属性和消长变化的学者之一；而后，管秉贤分析了黄海冷水团的水温变化和环流结构，并进一步确认黄海冷水团是冬季保留下来的。近几年来我国学者对黄海冷水团的成因和水文、环流结构又有不少新的研究。例如，袁业立提的热生模式较好地讨论了北黄海冷水团中心区域的热结构和环流结构；Guo Binghuo(郭炳火)根据南黄海冷水团分裂成两个低温中心，指出：围绕南黄海冷水团存在着大小两个气旋式冷水团环流。万国铭等1)依据经典的水团分析技术指出：南黄海冷水团仅分布于123°E以西的狭小区域，而123°E以东的广阔水域则为黄海暖流底层水所占据。赵保仁提出潮混合对黄海冷水团的边界起着重要的控制作用。以上几种观点，对进一步分析黄海的水团和环流结构都有着启发意义。 本文的主要目的，是依据1984年7月中美联合调查所获得的水文资料(站位见图1)和部分历史资料来阐明南黄海冷水团内部的复杂结构。分析结果表明，夏季南黄海深层冷水团内部，仍然存在着春季保留下来的具有高温高盐性质的黄海暖流水系的扩张现象。这一扩张现象似可理解为与黄海暖流同源但已被切断联系的黄海暖流残迹在黄海冷水团内部继续前进的反映。因此，夏季黄海冷水团可进一步划分为具有高温高盐性质的“黄海暖流水”和具有低温低盐性质的“黄海本地冷水”两个次级水团。在这两种水团之间，存在着明显的锋面和显著的混合现象，在锋面处还可以观测到由双扩散产生的两水团之间的相互侵入现象。     

黄海冷水团对海洋变动的响应

本文利用历史资料,分析了黄海夏季底层冷水团水温的冷暖变化与海洋变动之间的关系.结果发现,黑潮大弯曲的第二年为黄海冷水团的暖年、埃尔尼诺事件出现的当年为黄海冷水团的冷年,最后讨论了冷暖年黄海冷水团环流特征.     

台风过境对黄海冷水团及其环流结构的影响

台风能够对黄海的水文结构及人民群众的生产生活产生重要的影响,严重威胁了人们的生命财产安全。利用ROMS(regional ocean modeling system)模式,分析了台风"灿鸿"在过境黄海期间对黄海温度及环流结构的影响过程。结果表明,台风期间强烈的风致混合能够使温跃层的深度增大,强度减弱,同时,使得近岸的底层温度迅速升高,推动底层的温度锋面向黄海内区移动。台风过境也会对黄海冷水团环流产生重要的影响,台风过境前,混合层中的北向流会迅速加深增强,同时伴随着混合层及温跃层的下移,从而使得黄海冷水团环流的流核下移至跃层以下。当台风过境时,黄海上空的气旋式风场会加剧黄海上层的气旋式环流,导致黄海冷水团环流的流幅及流量迅速增加。当台风登陆后,黄海上层的温度及黄海冷水团环流的结构开始逐渐恢复。     

北黄海冷水团环流结构探讨──潮混合锋对环流结构的影响

简述北黄海冷水团环流结构研究现状，指出已有研究成果中的主要问题，然后用一个诊断模型给出了冷水团环流结构，得到冷水团环向主要存在于海洋上层接近冷水团边界处，径向运动也主要存在于断面两端，上层为离岸流，下层为向岸流；冷水团中心的上升流极为微弱，且仅存在于海洋上层，温跃层下的冷水团中心区域的流动极为微弱，几乎为“死水”一般，上述环流结构对冷水团中心部分的温、盐度长期保持不变及跃层底部溶解氧最大值的形成和     

黄、东海地理环境与环流系统分析——长江口及济州岛邻近海域综合调查研究报告(第二章)

简要介绍了黄海和东海的地理环境概况,着重分析调查海域的环流系统。有如下一些初步看法与结论。 台湾暖流的前缘混合水,可从长江冲淡水底层穿越而影响到苏北沿岸,直到32°N以北的浅水区域。对马暖流西侧的水体是东海混合水,而其东侧为黑潮分支。黄海暖流的流向在不同季节具有规律的摆动。黄海底层冷水团属于季节性水团,其强盛及消衰与温跃层的形成及消亡紧密相关。黄海底层冷水团与中部底层冷水并非每年彼此独立,它们的共同特征甚至比其差异更明显。夏季东海冷水不能借助爬升侵入黄海底层冷水团内部。在济州岛南部区域,中层的逆温、逆盐现象,是由黄海密度环流的扩散效应与东海冷水沿黄海底层冷水团边界的爬升这两个原因而形成的。     

渤、黄、东海夏季环流的三维斜压模型

基于拉格朗日时均观点描述环流，建立起潮流与准定常流共同占优势系统中的陆浅海环流模型，并诊断计算了夏季渤、黄、东海的三维环流图。模拟结果较好地再现了渤、黄、东海主要流系的特征。对照冬季结果，对渤、黄、东海环流的季节变化做了阐述。从环流垂向分量的分布图上，可发现渐闽近海、长江口外存在较明显的上升流区。另外，对夏季渤、黄、东海的热盐环流和潮致余流分别进行了模拟，发现它们均能在黄海构成一逆时针向的五流系统，这对形成和维持夏季黄海冷水团的存在有重要作用。热盐环流的模拟结果表明，黄海冷水团环流含有“热成流”的成分；通过Lagrange余流的计算发现环绕黄河冷水团的环流还含有“潮成流”的成分。     

青岛冷水团的生成与演变研究

本文基于现场观测资料并结合FVCOM三维海洋模式的模拟结果,研究了2010年青岛冷水团生消过程和演变机制。结果表明,山东半岛东南海域的中层冷水是青岛冷水团的雏形,于4月中旬演变为青岛冷水团,位于青岛东南外海40m以下的盐度锋面中;刻画了青岛冷水团的消亡过程:5月青岛冷水团的北部底层水并入南黄海底层冷水中,构成南黄海的西部冷中心;而南部水团面积大幅减小,温盐特征大幅上升;6月上旬,青岛冷水团完全被南黄海底层冷水吞并,青岛冷水团完全消亡;揭示了青岛-石岛近海反气旋涡、黄海冷水团锋面密度环流对青岛冷水团的作用,前者是青岛冷水团存在的动力机制,后者加剧了底层海域的水平热量交换,促使了青岛冷水团的消亡。     

渤海沿岸流季节变化对青岛冷水团影响的初步分析

青岛冷水团位于青岛外海海域,具有独特的温盐结构和生消规律,对近海水文和周围渔场有重要的影响。利用世界海洋数据库(WOD2013)和中国科学院海洋研究所开放航次的黄海断面观测资料,及ROMS区域海洋模式,对青岛冷水团的形成机制和演化过程进行了研究。结果表明,青岛冷水团3月初现,4月形成,5月达到鼎盛,6、7月逐渐与黄海冷水团融合,8月开始衰减至10月消亡。渤海沿岸流秋冬季为北风驱动的正压流,其携带的山东半岛北岸的低温水为青岛冷水团的形成提供水源;春夏季为冷水团密度环流,输运到青岛冷水团和黄海西侧冷水团之间的低温水促进了两水团的融合,加快青岛冷水团的消亡。     

黄海南部及东海北部夏季若干水文特征

本文就近几年作者在黄海南部和东海北部进行调查研究(夏季)的主要成果予以阐述,结论为:(1)南黄海底层冷水可进一步划分为三个次级水团;(2)潮混合对黄海冷水团边界和黄海温跃层等有重要影响,它还形成海面的陆架锋;(3)夏季南黄海上层存在着闭合的密度环流,而黄海沿岸流性质上属锋面强流,济州岛西南存在着气旋式海水运动;(4)黄海暖流不再深入黄海冷水团内部,但其内部可能存在着方向相反的一对弱环流;(5)长江口海区存在着可能是因台湾暖流逆坡行进产生的上升流现象。     

Hadley and Rossby regimes in a simple model of convection of a rotating fluid

This paper analyzes the properties of solutions to the equations describing the motion of a stratified fluid in the class of velocity and temperature fields linear in coordinates. For an ideal fluid, these equations, on the one hand, are exact for the corresponding hydrodynamic problem and, on the other hand, are identical to the equations of motion for a heavy top. In a conservative case, the equations of motion of a top share common solutions with the equations of geophysical fluid dynamics and reproduce motions similar to those existing in the theory of the large-scale atmospheric circulation. This study considers the effects of viscosity and heat conduction in the fluid, which are, in a sense, similar to the effect of friction in the case of a top. The influence of deflections of the vectors of gravity and external rotation from their standard directions for a plane-parallel atmosphere is also considered. The regimes of motions that are described by the starting equations and approximations commonly used to model the atmospheric general circulation (the quasi-geostrophic approximation) are analyzed. It is shown that these equations correctly describe the Hadley and Rossby circulation regimes and transitions between them that are observed in numerical and laboratory experiments. Particular attention is given to the consistency between different regimes of the exact equations and their quasi-geostrophic approximations, which is manifested for small Rossby numbers and is generally absent for large Rossby numbers. The asymptotic behaviors of the curves of transition between the Hadley and Rossby regimes under the conditions of breaking the external symmetry of flows are obtained. These asymptotics explain the corresponding transition boundaries for the regimes observed in the known experiments in annuluses.     

东海西北部中层冷水垂直热结构数值预报方法研究 Ⅱ.三维数值预报模式

根据含中层冷水海洋垂直热结构的特征,将其分为4层,并考虑来自海面的热力和动力强迫因子、水层界面剪切应力和卷挟热交换、热平流、混合及地形影响等条件下,从原始动量、连续方程组及热传导方程出发,对整个海洋和各水层分别进行垂向积分,导出相应的描述风生界面起伏、各水层平均流场和温度场的闭合方程组.当解得各水层的平均温度场T_k(k=1,2,3,4)后,根据Tk与对应水层界面特征温度间的关系获得后者,最后通过水温剖面表达式获得含中层冷水海洋的三维热结构.为了检验本模式的功能,以时效为5d试报了5月15日研究海域的三维热结构,并将试报结果与实测值进行了比较.结果表明,试报水温的均绝误差为025℃,效果令人满意.     

A numerical study on the tidal residual flow

Characteristics of the tidal residual flow, the steady current induced in the tidal current system, are studied by a numerical method. The model basin has the same topography as that studied byYanagi (1976) and byOonishi (1977) where only the horizontal motion of the residual flow is concerned. In this study, the effect of the vertical motion is investigated as it is associated with the tidal residual flow. To this end, the bottom friction omitted in the previous study (Oonishi, 1977) is included and a two-leveled model is adopted.The first two experiments exclude the earth's rotation and the buoyancy effect on the flow. The results are as follows. The horizontal flow pattern is essentially the same as that obtained in the previous Oonishi study. The bottom friction results in the reduction of the velocity of the residual flow especially in the bottom level. An important result is that vertical velocity is as strong as the horizontal velocity multiplied by the scale ratio and that it remains even in the time-average. Upwelling appears at the center of the residual circulation. This upwelling explains Yanagi's observation in the hydraulic model that the sediment is swept by the flow and accumulates horizontally in the area at the bottom below the center of the residual circulation. The distribution of a tracer, which is simultaneously calculated in these cases, indicates the important role of vertical motion in the material dispersion in the model.The last experiment includes the earth's rotation and the buoyancy effect presuming a more actual sea. It shows another effect of the vertical motion. The Coriolis term, which operates only under the condition that a horizontal divergence of the flow is present, skews the horizontal residual flow pattern.     

Numerical modeling of the propagation of nonlinear acoustic-gravity waves in the middle and upper atmosphere

A numerical algorithm for modeling the vertical propagation and breaking of nonlinear acoustic-gravity waves (AGWs) from the Earth’s surface to the upper atmosphere is described in brief. Monochromatic variations in the vertical velocity at the Earth’s surface are used as an AGW source in the model. The algorithm for solving atmospheric hydrodynamic equations is based on three-dimensional finite-difference analogues of fundamental conservation laws. This approach selects physically correct generalized solutions to hydrodynamic equations. A numerical simulation is carried out in an altitude region from the Earth’s surface to 500 km. Vertical profiles of the background temperature, density, and coefficients of molecular viscosity and heat conduction are taken from the standard atmosphere models. Calculations are made for different amplitudes of lower-boundary wave forcing. The AGW amplitudes increase with altitude, and waves may break in the middle and upper atmosphere.     

Seasonal variability of climatic currents in the Caspian Sea reconstructed by assimilation of climatic temperature and salinity into the model of water circulation

We present the results of an analysis of the seasonal variability of current fields in the Caspian Sea, reconstructed by assimilation of climatic temperature and salinity into the primitive-equation model of water circulation on the basis of an algorithm for adaptive statistics of prediction errors. The sources in heat and salt transfer-diffusion equations depend on the spatial and temporal variability of the variances of prediction errors and one-dimensional (in the vertical coordinate) variances of measurement errors for temperature and salinity. The variances of prediction errors are adjusted at the moments of data assimilation in accordance with a simplified Kalman filter. The climatic circulation of waters in the Caspian Sea is shown to be highly varying. The maximum of its intensity over the entire depth is reached in February. The minimum of kinetic energy is observed in April. The currents in deep-sea areas are determined by the balance between wind and baroclinic factors of the formation of circulation with wind currents prevalent.     

Diagnostic analysis of water circulations in Lake Biwa

A diagnostic model is developed for the study of steady water-circulations during summer in Lake Biwa. The most characteristic feature of the present model is to include the vertical friction terms in the basic equations, so that it is not necessary to assume a level of no-motion. Under no-wind condition, the velocity field is calculated from the density field obtained by successive observations of water temperature using a bathythermograph.The comparisons of the present calculation with a dynamical calculation and direct current measurements indicate that the present model surpasses a dynamical calculation in the respects that 1) vertical circulations can be estimated and 2) the flow pattern in the deep layers can be obtained more reliably. One of important results of the present calculation is that a large vertical circulation has been found accompanied by the large counterclockwise gyre in the north basin. Preliminary results of direct current measurements by cross-boad drogues also seem to suggest the existence of the circulation.     

A method of simultaneous analysis of wind and temperature profile data over the water surface by use of the method of least squares

Priestley’s 1959 discussion concerning the estimations of momentum flux and of heat flux from profile observations of wind and temperature, stating that the closeness of the curve fitting is deceptive, is first critically re-examined. Then a method is proposed to estimate vertical flux of momentum and heat over the water surface, from the combined data of of wind speed and temperature are assumed to have similar log-linear profiles, and the most probable profiles are determined by applying the method of least squares simultaneously to wind and temperature data. Consequently, the most probable values of vertical flux of momentum and heat may be estimated to satisfy as much as possible observed data of both wind and temperature simultaneously. The coefficient of the linear term of the log-linear profile, which is treated as an indeterminate coefficient in this method, may be determined from each observed data as a function of stability length. By tentatively applying the method to Rider’s 1954 data it is found that the coefficient shows a characteristic behavior with the stability length.     

Theoretical Analysis of A Buoyant Jet Interacting with Small Amplitude Waves

A new theoretical solution is presented here for the dynamic characteristics of a buoyant jet due to opposing small amplitude waves.The conservation equations of mass,tangential momentum and vertical momentum are solved by the integral method which encompasses the Gaussian profiles of velocity and density.The action of waves is incorporated into the equations of motion as an external force and a new exact solution is obtained to predict the trajectory,velocity distribution and boundary thickness of the buoyant jet over an arbitrary lateral cross section.It is found that the velocity along the centerline is inversely proportional to the ratio of the momentum of the wave to the buoyant jet.The averaged boundary width varies with the fluctuation of the boundary width,the distance from the orifice and the velocity correction function.Owing to the motion d waves,the fluctuation of the boundary width is proportional to the wave steepness.     

Vertical structure of the quasi-two-dimensional velocity field of a viscous incompressible flow and the problem of nonlinear friction

An approximate theory is constructed to describe quasi-two-dimensional viscous incompressible flows. This theory takes into account a weak circulation in the vertical plane and the related divergence of the two-dimensional velocity field. The role of the nonlinear terms that are due to the interaction between the vortex and potential components of velocity and the possibility of taking into account the corresponding effects in the context of the concept of bottom friction are analyzed. It is shown that the nonlinear character of friction is a consequence of the three-dimensional character of flow, which results in the effective interaction of vortices with vertical and horizontal axes. An approximation of the effect of this interaction in quasi-two-dimensional equations is obtained with the use of the coefficient of nonlinear friction. The results based on this approximation are compared to the data of laboratory experiments on the excitation of a spatially periodic fluid flow.     

Hydrodynamic forces on submerged vertical circular cylindrical tanks under ground excitation

This paper investigates hydrodynamic pressures and forces on submerged vertical cylindrical tanks under the action of harmonic ground excitations. Water is assumed to be imcompressible and inviscid, motion irrotational and waves are of small amplitude. Semi-analytical method is used for the solution, that is, the fluid domain is divided into inner and outer regions. The Laplace equations governing velocity potentials for the two regions are solved by separation of variables and expressed in terms of eigenfunctions of the resulting equations which satisfy appropriate boundary conditions. Continuity of pressure and velocity at the interface of the inner and outer regions provides the necessary equations from which the velocity potentials, pressures and forces are obtained. Numerical results are presented in graphical form for forces and pressures for a range of excitation frequencies for selected proportions of tank geometry and water depth.