乐清湾内外潮波变形及不对称性分析

海湾内外的潮波变形及其不对称性影响海湾内外动力输送和水体交换。利用乐清湾内外共9个测站连续潮位进行调和分析,得到该海湾内外各分潮变化规律,利用潮不对称性偏度计算方法确定湾内外潮汐不对称性时空变化特征,比较了主要分潮组合对潮汐不对称性的贡献度,通过数值研究探讨了湾内偏度比湾外偏度值更小的主要成因,分析了湾内外围垦工程对潮不对称偏度的影响。研究发现:乐清湾内潮汐不对称偏度值为负,表现为落潮占优,同期湾外洞头站偏度值为正,与邻近瓯江、飞云江河口的潮不对称偏度变大、表现涨潮占优的变化规律相反;湾外沿岸各站偏度由东北向西南逐渐增大,由落潮占优向涨潮占优变化;潮汐不对称性偏度呈周期性变化,分析确定M2-M4、M2-S2-MS4分潮组合对潮不对称贡献大,该海域潮汐不对称的强度主要由浅水分潮振幅控制,而相对相位则决定潮汐不对称的方向;数值研究探讨表明,湾内大范围的浅滩地形是其潮汐不对称落潮占优的主要原因,围垦将削弱湾内的落潮占优。     

河口回水动力的演变过程及其影响机制

河口回水区长度的时空演变对防洪、供水、航运等水资源高效开发利用具有重要指导意义。本文在经典河流回水理论的基础上考虑潮汐动力的影响,聚焦潮汐动力引起的回水效应问题,基于一维水动力解析模型,重新定义河口回水区上游界限（回水界）,并以长江河口为例,探讨河口回水动力演变过程及其影响机制。结果表明:回水界距天生港的距离（即回水区长度）与上游流量、外海边界振幅分别具有显著的负相关和正相关关系,且基本为线性关系;回水界对径潮动力的响应比潮区界更为敏感,能有效表征河口感潮河段径潮动力格局演变;长江河口回水界位置具有明显的季节性差异,其春季和秋季回水界位于芜湖附近（春季和秋季分别距天生港419 km和367 km）,冬季回水界位于感潮河段以上区域,夏季潮汐动力引起的回水效应基本可忽略;长江河口潮流因子和径潮相互作用因子控制的余水位梯度的季节性变化,是长江河口回水界位置变动的主导因素。     

伶仃洋洪季潮波传播变形及不对称性规律分析

珠江河口伶仃洋水域潮波传播变形及其不对称性关系对河口动力环境和物质输运产生影响。研究根据珠江口伶仃洋及东四口门19个潮位站2011年6月实测逐时潮位, 利用收缩河型沿程潮幅解析理论, 阐释伶仃洋从桂山岛上行沿程潮汐传播规律特征; 在调和分析基础上, 应用偏度理论和分潮组合分析方法, 阐明了伶仃洋东西岸及洪奇门、蕉门内潮汐不对称性分布特征, 对照数值研究结果, 指出伶仃洋至虎门之间水域导致潮汐不对称性的主控因素及响应规律。研究表明, 河口平面形态呈近似指数收缩特征的伶仃洋, 沿程潮幅的变化符合指数收缩型河口波幅解析变化规律, 东岸潮幅高于西岸的主要原因是东岸水深大于西岸, 其次是科氏力影响; 行进潮波虽受地形摩擦耗能及非线性作用下不同频率分潮间能量迁移的影响, 但收缩河口能量汇聚效应可以保证收缩段天文分潮潮幅减缓衰减甚至增加, 半日分潮能量汇聚效果强于全日分潮, 各非线性项作用促使浅水分潮产生并持续增能, 保证一定距离内沿程潮幅的增大; 潮汐不对称性的偏度由湾口落潮占优向湾顶涨潮占优发展, 在伶仃洋中部赤湾至金星港一线转为涨潮占优, 产生该现象的原因是自湾口向湾顶不同频率间天文分潮K₁-O₁-M₂的相互作用, 导致表现为落潮优势潮的不对称性减弱, 而天文分潮M₂和其对应的浅水分潮倍潮M₄组合作用使涨潮优势偏度值的不对称性增强; 收缩河口形态属性要素中, 水深是影响潮不对称性的最主要因素。     

潮汐汊口水流结构和动力特性研究

潮汐汊口作为河网的重要单元,关系到水沙以及可溶污染物、营养物质的输运和分配,对河口三角洲的水文过程、地貌沉积和生态环境,都有至关重要的影响。本文选取国内最大的珠江河网的分汊顶点-马口、三水分汊,基于一个大潮潮周期内走航ADCP测量,分析潮汐汊口各个支汊的流速过程及三维流速的时空分布特征;结合非稳态的调和分析算法和小波连续变换确定汊口处主要的潮汐组分,利用潮流分离技术,剥离出占主导作用的潮波信号并探讨潮波动力在潮汐汊口处的空间分布形态。研究发现,由于潮波在西江马口和北江三水汊道内传播的不对称性,两汊间的流速过程存在1.5 h左右的相位差。而连接西北江的岗根汊道,由于存在频繁的水体交换和弯道水流的特性,岗根断面的动力作用较为复杂,其最大垂向平均流速在涨落急时刻分别向左、右岸偏移,横向断面均出现了显著的顺时针二次流。     

利用潮汐动力减轻深圳河污染的水力条件计算分析

建立了深圳河非恒定流数学模型，模型中考虑了过闸水头突变的计算方法，采用拉格朗日法研究深圳河上游的罗芳污水处理厂和滨河污水处理厂所排出污水沿深圳河的运动过程，计算分析了利用潮汐动力减轻深圳河污染的水力条件。结果表明，深圳河口建闸3种不同调控方案下污水运移至深圳河口的总时间有所增加，这对于减轻深圳河的污染情况不利；从大鹏湾抽调清水以增加上游来水量则会大大缩短污水运移至深圳河口的时间，从而减轻深圳河的污染状况。     

滦河三角洲海岸潮汐汊道——潮盆体系的演变

近二千年以来，滦河尾闾从西向东迁移，形成了由不同时期的亚三角洲互相叠复而成三角洲体系。丰富的入海泥沙和弱潮环境使该三角洲海岸发育了我国较为完整的潮汐汊道——潮盆体系群。尽管滦河三角洲与密西西比河三角洲有诸多相异之处，但动力泥沙条件的某些相似性使它们的汊道潮盆体系的演变可以进行类比。研究表明，决定潮汐汊道——潮盆体系发育阶段的是它所在的亚三角洲的废弃年龄。从狼窝口到湖林口的各亚三角洲均处于演变的第一阶段。即以受蚀陆岬及其沙咀状堡岛为特色的第一阶段。而大清河口附近则处于以堡岛弧为代表的第二阶段。目前，曹妃甸附近的亚三角洲正在向第三阶段，即堡岛演化为内陆架浅滩的阶段演化。从现代滦河口向曹妃甸，对应于废弃年龄的增加，潮汐汊道分别属于五种类型，即新生波浪型、新生过渡型、潮汐型、老年过渡型及老年波浪型     

长江口新桥水道潮汐不对称性研究

涨潮槽是河口重要的地貌类型,其潮汐动力受地形摩擦、径流及风浪等因素影响而发生不对称现象,直接影响槽内的泥沙动力过程。本文基于实测数据与数值模型计算潮汐不对称偏度,研究长江口南支最大的涨潮槽——新桥水道的潮汐不对称性及其影响因素。结果表明：（1）受余流与各分潮的相互作用控制,新桥水道可分为三个区域,上段为涨潮优势区域,中段为涨落潮转换区域,下段是落潮优势区域。（2）新桥水道欧拉余流表现出明显的分段差异,上段指向陆而在中下段指向海并受到径流影响。斯托克斯余流则均指向陆并向陆增强。（3）新桥水道内中下段潮汐不对称受地形的影响较大,其中扁担沙的北移增强了新桥水道中段的涨潮优势特性,新的新桥通道的形成促进了新桥水道下段的落潮优势特性。     

珠江河口潮能通量与耗散

珠江河口三角洲是我国一个极其复杂的大尺度河口系统,具有独特的河网体系和河口湾.为探讨珠江河口三角洲的潮能通量和潮能耗散机制,基于SELFE模型,建立了珠江河网-河口湾的三维数值模型,计算了河网-河口湾区的潮能通量和潮能耗散.研究表明:珠江河口的潮能通量平面上表现出主槽大,滩地较小;在总能耗中,底摩擦能耗最大,其次是垂向扩散耗散能耗,水平扩散能耗最小;存在‘门’、分汊汇流区和弯曲河道区等典型的高能耗区,高能耗区的单位面积能耗比附近水域的高数倍甚至1～2个数量级.     

河口三角洲径流和潮汐相互作用模型及应用

受径流影响和调制,径优型河口潮汐的非线性作用强,潮汐调和分析和预报误差大。文章在调和分析方法的基础上,结合河口三角洲内径潮相互作用机理,假定河道地形变化微弱,采用实测潮水位和上游径流量,建立径流和潮汐调和分析(river-tidal harmonic analysis,简称RTHA)模型,用于分析和研究珠江三角洲的径流和潮汐的相互作用过程。结果表明,对于珠江河口年尺度的潮水位数据,RTHA模型分析和预报的标准误差0.12~0.17 m,方差贡献(相关指数)为91%~98%,特别是在径流作用强的河口三角洲中上段,RTHA模型结果远高于传统的调和分析和预报结果,可以以较高精度分离径流和潮汐信号。利用该回归模型对珠江径流影响下非线性潮汐的变化进行研究,结果发现,珠江径流量的洪枯季变化引起河口全日分潮、半日分潮、三分之一分潮的振幅洪季小、枯季大,口门段四分之一分潮的振幅洪季大、枯季小;洪季全日分潮、半日分潮传播速度变小(位相增大),分潮振幅沿程衰减幅度显著增大,自枯季的10%~30%迅速增加到洪季的70%~80%。     

非结构网格三维斜压模型研究人类活动对海南岛清澜潮汐汊道水动力影响

清澜潮汐汊道为海南岛东部一个典型的泻湖-潮汐汊道-沙坝系统,由于其优越的自然条件而成为开发的重点区域。近几年的人类活动主要包括:口门西侧的围填工程,航道的疏浚和八门湾泻湖内的围塘工程。采用SELFE模型,结合观测资料,研究了不同人类活动对潮汐汊道的潮波、潮通量与涨落潮历时、河口重力环流、盐水入侵和河口羽流的影响。结果表明不同的人类活动其对动力的影响不同,口门西侧围填工程减小了潮汐汊道的潮差,对潮通量和盐水入侵影响很小;航道疏浚则加大了潮差和潮通量,加强了河口环流和盐水入侵;泻湖内围塘工程使潮差有所增大,但减小了潮通量,对盐水入侵的影响不显著。口门西侧围填工程改变了河口羽流的路径,而航道疏浚则使河口羽流更加向海扩散。     

Response of sediment dynamics in the York River Estuary,USA to tropical cyclone Isabel of 2003

Tropical Cyclone Isabel of 2003 generated large storm surge, strong waves, and subsequent river flooding in the York River Estuary, USA during its passage across the Chesapeake Bay region. A 3D model was used to investigate the changes of sediment concentration, sediment flux, and the recovery time of the York River Estuary to its naturally evolved condition without the storm. The results showed that two sediment concentration peaks appeared during the storm event. The first one was induced by the large upstream flow and waves during the storm surge rising period, and the later one was caused by the strong downstream flow during the descent of the storm surge. The advection, which was induced by the barotropic gradient, dominated the sediment flux during the storm event. The sediment fluxes increased by a factor of 100 during the rise and descent of the storm surge. A large amount of sediment that was transported into the estuary and eroded from the seabed during the rising of the storm surge was quickly transported out of the estuary during the descent of the storm surge. Waves played a key role in stirring the seabed and increasing the sediment concentration during the storm. Subsequent high freshwater inflow changed the sediment loading and hydrodynamics in the estuary, and thus, influenced the estuarine turbidity maximum (ETM) dynamics profoundly. The ETM moved downstream with the river flooding initially and returned upstream with the waning of river flooding and the re-establishment of gravitational circulation. The effect of river flooding on sediment concentration varied spatially and depended on the changes of ETM locations and vertical mixing. The model results suggest that a large amount of sediment was transported out of the estuary during the storm event and the subsequent river flooding had a larger impact on recovery time of the estuary.     

Methodology for estimation of river discharge and application of the Zhujiang River Estuary(ZRE)

The ZRE is a very complicated estuary with multi-river inlets. The total sum of river discharge in the upstream(away from the tidal influence region) of the Zhujiang River can be easily measured. However, when the total river discharges into the estuary from eight inlets, it is a very difficult task to obtain a continuous river discharge flux data from each branch of the Zhujiang River. However, the different ratios of river discharges between the river branches can significantly affect the estuarine circulation feature and baroclinic process. Moreover, the accuracy of numerical forecast for the estuarine circulation is very much dependent on the accuracy of the time history of the river discharge flux for each branch. Therefore, it is important to estimate river discharge from each branch in order to improve the accuracy of the model forecast for the circulation of the ZRE. The development of a new estimation method of the river discharges is focused on based on the system identification theory, numerical modeling and the time history data from the CODAR observed sea surface current. The new approach has been appfied to estimating the time history (hourly) of river discharge from each branch in the upstream of the ZRE.     

Using salt intrusion measurements to determine the freshwater discharge distribution over the branches of a multi-channel estuary: The Mekong Delta case

The fresh water discharge is an important parameter for modelling salt intrusion in an estuary. In alluvial converging estuaries during periods of low flow, when salinity is highest, the river discharge is generally small compared to the tidal flow. This makes the determination of the fresh water discharge a challenging task. Even if discharge observations are available during a full tidal cycle, the fresh water discharge is seldom much larger than the measurement error in the tidal discharge. Observations further upstream, outside the tidal region, do not always reflect the actual flow in the saline area due to withdrawals or additional drainage. Discharge computation is even more difficult in a complex system such as the Mekong Delta, which is a multi-channel estuary consisting of many branches, over which the freshwater discharge distribution cannot be measured directly. This paper presents a new approach to determine the freshwater discharge distribution over the branches of the Mekong Delta by means of an analytical salt intrusion model, based on measurements made during the dry season of 2005 and 2006. It appears that the analytical model agrees well with observations and with a hydraulic model. This paper demonstrates that with relatively simple and appropriate salinity measurements and making use of the analytical salt intrusion model, it is possible to obtain an accurate discharge distribution over the branches of a complex estuary system. This makes the analytical model a powerful tool to analyze the water resources in tidal regions.     

The hydrodynamic response of the York River estuary to Tropical Cyclone Isabel, 2003

Hurricane Isabel made landfall along the North Carolina coast on September 18, 2003 (UTC 17:00) and the storm surge exceeded 2.0 m in many areas of the Chesapeake Bay and in the York River estuary. River flooding occurred subsequently, and the peak river discharge reached 317 and 104 m³ s⁻¹ in the Pamunkey and Mattaponi rivers, respectively. The York River estuary experienced both storm surge and river flooding during the event and the estuary dynamics changed dramatically. This study investigates the hydrodynamics of the York River estuary in response to the storm surge and high river inflows. A three-dimensional model was used to investigate the changes of estuarine stratification, longitudinal circulation, salt flux mechanisms, and the recovery time required for the estuary to return to its naturally evolved condition without the storm. Results show that the salt flux was mainly caused by advection, which was induced by the barotropic gradient during the storm event. The net salt flux increased by a factor of 30 during the rise of the storm surge. However, the large amount of salt transported into the estuary was quickly transported out of the estuary as the barotropic gradient reversed during the descent of the storm surge. Subsequent high freshwater inflow influenced the estuarine circulation substantially. The estuary changed from a partially mixed estuary to a very stratified estuary for a prolonged period. The model results show that it will take about 4 months for the estuary to recover to its naturally evolved salinity distribution after the impacts of the storm surge and freshwater pulse.     

黄河河口三角洲风暴潮灾害特点及其预防对策

黄河河口三角洲地区是风暴潮灾害的多发地区,研究该地区风暴潮的成因及其特点,是有效预防风暴潮灾害的基础。在对风暴潮成因分析的基础上,重点研究了各类风暴潮的特点,并提出预防风暴潮灾害的对策措施。     

一个潮流不对称计算方法及其在北仑河口的应用

河口近岸海域潮流不对称对于物质输运、地形地貌变化有重要作用,因此研究河口近岸海域潮流不对称具有重要的意义。从统计学角度出发推导了一种潮流不对称的计算方法,并将该方法应用于全日潮类型的北仑河口。研究认为:从三阶原点矩出发推导的计算方法能够合理的量化潮流不对称;潮流不对称的方向由分潮的相对相位决定,不同分潮对潮流不对称的影响大小由其相对振幅和相对相位共同决定;在正规全日潮海区,三阶原点矩即可满足对潮流不对称的计算。北仑河口潮流表现为落潮流速占主导,潮流不对称空间上表现为口门强于外海,浅滩强于深槽。     

温州近岸围堤对风暴潮漫滩影响的数值研究

利用-套基于非结构网格且能计算海水漫堤溢流的超高分辨率风暴潮漫滩数值模式模拟由9417号台风特大风暴潮引起的漫滩,结果与实测吻合良好。此外,选取超强台风强度并以9417台风路径为南路径,往北每间隔30 km为中路径和北路径设计了3条台风路径,进行了-系列数值模拟得出:近岸围堤加大了风暴潮、漫滩淹没对温州的威胁,而且由南路径引起的漫滩深度和中路径引起的漫滩面积影响最大。究其原因,近岸围堤对外海风暴潮在温州近海及瓯江口传播的阻隔和分流作用,两者综合变相加大了风暴潮往瓯江口北侧海域、瓯江北口、瓯江中上游的输送量。     

现代黄河三角洲地面沉降对洲体演变的影响

对现代黄河三角洲地区地面沉降的特点和对三角洲发育演变的影响进行了分析研究。分析认为,现代黄河三角洲地区普遍发生的地面沉降具有多因素和时空不连续性的特点,给沉降区带来了一系列的危害,使多种海岸带灾害的破坏和影响加剧;地面沉降不仅可以造成地面标高损失,影响三角洲的垂向发育,还通过改变地面坡降来影响河道的演变和尾闾的摆动,同...     

风暴潮前后莱州湾西岸滩演化特征研究

Multiple surveys were conducted before and after storm surge at four beach sections,Sediment samples were analyzed and numerically simulated for understanding the characteristicsof becach reaction to storm surge and morphological evolution ,The results show that the sediment sources in this area do not increase in amount;the beach is basically stable in normal weather.While in gale weather,sediment from Yellow River and the eroded matters from the bank becomes a part of the sediment sources.The northem beach of Xiaoqing estuary is eroded seriously, while the southern beach is overall stable,Thw tidal creeks changed from the northern beach are transported greatly sea-ward and the inshore sediment becomes sandy,while that of the southem beach becomes silty,The sand transporting capability is almost 100 times of that in nomal weather. Human activities and big storm surges are the main reasons for the beach evolution.     

System Analysis of Disaster Prevention Design Criteria for Coastal and Estuarine Cities

—In China,estuarine and coastal cities are mostly regional economic development centers.Thedisasters by combined effect of upper reach flood,storm surge and typhoon waves are primary obstaclesto the economic development of such cities.Thus the risk analysis and system analysis of flood-stormsurge-wave disaster,economic loss and flood-storm surge control measures play a very important role inthe sustainable development of coastal cities.There are three types of coastal cities for consideration.Thefirst type of city is like Tianjin.The most significant damage is from the upper reach flood.The effect ofstorm surge is negligible,because in the estuary of the Haihe River,tidal locks are built.The Grey MarkovModel(GMM)is used to forecast the flood peak level.GMM combines the Grey system and the Markovtheory into a high-precision model.The predicted flood peak levels are close to the measured data.A syn-thetic model is established for economic assessment,risk analysis and flood-control benefit estimation.Asa n