台风"桃芝"北上加强原因浅析

2001年8号台风“桃芝”,登陆填塞后又重新发展加强,并在北移中给山东半岛带来特大暴雨。本文通过分析认为,低值系统同位相叠加和冷空气侵入是台风重新发展加强的主要成因;而冷槽“逆转”和副热带高压从日本向朝鲜半岛发展,导致我国东部径向环流加强,南风急流加大,则是台风北移的主要原因。     

Coastal geomorphic evolution at the Denglou Cape, the Leizhou Peninsula

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基于漂流浮标观测分析日本福岛以东表层海洋物质的散播轨迹

认识海洋中的物质如何散播对于理解海洋环境变化和人类活动污染在海洋中的扩散过程具有非常重要的意义。利用历史海表漂流浮标观测数据,对日本福岛以东海域的表层物质散播轨迹进行了拉格朗日示踪分析和观测模拟试验研究。结果发现,福岛以东海域海表浮标的散播路径主要分为东、南两支,其中速度较快的东支为主要通道,沿黑潮延伸体汇入北太平洋流,最短用时大约22个月即可到达北美西海岸;南支则沿黑潮延伸体以南的大范围南向流向西南方向运移,速度较慢且明显受涡旋活动影响,最快大约5个月即可到达吕宋海峡和中国台湾以东海域,进而进入南海和东海等中国近海海域。通过开展观测模拟试验,发现海表浮标散播的概率密度分布呈现以福岛附近海域为核心、向西南和正东方向递减扩展的形态,其中,到达中国近海的浮标主要通过吕宋海峡进入。文章详细讨论了研究结果的局限性、不足之处,以及因基于大量现场观测而具备的重要参考价值。     

赤道印度洋海温偶极子的气候影响及数值模拟研究

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.     

中国近海及其邻近海域海气热通量的模式计算

应用美国宇航局Goddard地球观测系统四维资料同化系统计算和分析了近海海域感热通量和潜热通量的季节性变化规律和地理分布特征.结果表明,近海各季感热通量冬、秋季较大,春、夏季较小.其地理分布特点是冬季感热通量的分布随纬度变化十分明显,纬度越高感热通量越大,且等值线分布密集.在台湾以东、日本以南海域,感热通量等值线呈西南一东北走向.在南海海域,感热通量比周围海域略低,感热通量等值线在该海域呈一低值倒槽分布;潜热通量冬、秋季在台湾东北部、日本南部和东南部海域形成最大值区,等值线呈西南东北走向.春、夏季在黄海海域存在潜热通量的极小值区,同时春季在日本南部海域存在潜热通量的极大值区或最大值区.因为台湾以东、日本以南海域正好是黑潮流经的区域,所以此海域的热通量与黑潮有密切关系.     

南印度洋副热带偶极子型海温异常与全球环流和我国降水变化的关系

用1951~2001年观测资料,研究了南印度洋副热带偶极子型(IOSD)海温异常对全球500hPa环流和我国降水的影响.结果表明,冬季IOSD激发出极显著的南北半球环绕太平洋的波列结构(CP),其年际变化周期是2.0和6.5 a,与赤道中东太平洋海温也有密切联系.北半球冬季异常峰值后的第二年春季欧亚中高纬度地区500 hPa环流出现显著的EUP型低频流型持续异常,同时中太平洋和北美地区出现CPNP流型和澳大利亚南部的南半球中高纬地区呈现极显著的西南太平洋遥相关型(SWP).当冬季赤道南印度洋副热带呈极显著的西负东正海温距平分布时,后期春季欧亚中高纬地区负EUP型遥相关波列持续偏强,导致东亚大槽明显偏弱,长江以北地区(特别是黄河中上游地区)多雨.反之,春季东亚大槽加强且稳定,我国东部地区大范围少雨.它反映了南印度洋地区海气系统相互作用与东亚热带内外环流低频变化的联系.因此,上一年冬季南印度洋副热带偶极子型(IOSD)海温异常强度是预测春季华北地区旱涝变化的重要因子之一.     

亚洲特有种——卵圆扁蝼蛄虾鳃虱的形态特性及地理分布分析

作者详细观察并记录了中国山东烟台优势种卵圆扁蝼蛄虾鳃虱(Gyge ovalis Shiino,1939)的形态学特征,比较了不同地域该种的形态学差异,应用扫描电镜技术,发现了该物种雄性个体的关键鉴定特征。研究结果表明:中国、日本、韩国的卵圆扁蝼蛄虾鳃虱在形态特征方面雌性个体差异较大,雄性个体差异较小;卵圆扁蝼蛄虾鳃虱的地理分布相对较集中,主要分布在中国山东和台湾两省、韩国、日本,确定其为亚洲特有种;通过扫描电镜,首次发现卵圆扁蝼蛄虾鳃虱的雄性个体中腹突上有呈鳞片状分布的"锯齿"状刚毛。     

东秦岭早古生代古海洋研究

本文在岩石地层，古生物，沉积地球化学，流体包裹体研究的基础上，运用古地磁学与构造地质学原理与方法对东秦岭早古生代古海洋的构造演化及其构造古地理格局进行了系统的，定量化研究，从不同的角度论述了古秦岭海的发展与演化。     

Angle of energy flux at the origin of two major tsunamis

The energy flux of the Japan Sea Tsunami of May 26, 1983 radiated offshore causing the destruction of ships in Shimane Prefecture, the fourth worst area hit. In 1960, a tsunami from Chile attacked the Pacific coast from the Ryukyu Islands to Adak Island Alaska. The energy flux of the latter was similar to that of the former. The angle formed at the origin off the Chilean coast by the energy flux was 68°48 or possibly slightly larger. The coincidence between the angle given by this process and that by the directivity theory of Miyoshi (1977) is good. The Sanriku District is located approximately on the center line of this angle. Judging from the fact that the Sanriku District was attacked most severely in 1960, it can be suspected that the energy flux was a little more sharply directed than estimated by the theory. The equivalent angle in the case of the Japan Sea Tsunami, which attacked the area from the tip of the Noto Peninsula to the east coast of the Korean Peninsula, was only 45°30 and the smaller angle can be explained as a refraction effect of the Yamato Bank. The above information should be useful for warnings of future tsunamis.     

Sudden strong current generated by an eddy in the eastern part of Wakasa Bay,Japan

A sudden strong coastal current called a “kyucho” occurred in August 2013 in the eastern coastal waters of Wakasa Bay, Japan. This study examined its characteristics based on both observational data collected by intensive field investigations and the simulation results of a numerical model. The field investigations comprised moored buoy observations near the coast and voyages by a research vessels and fishing boats. The mooring observations indicated that a current speed exceeding 50 cm s^?1 occurred abruptly near the eastern coast of the bay, in association with a synchronous change in the current direction. Data collected by acoustic Doppler current profilers (ACDPs) mounted on the vessels showed that a clockwise eddy existed in the bay and that the current on the east side of the eddy generated the kyucho near the coast. Based on the results of the numerical model and the analysis of the ADCP data, it was considered that the clockwise eddy was generated by a strong current at the tip of the Tango Peninsula, in the western part of the bay. As the eddy propagated from west to east across the bay, it induced the kyucho in the coastal waters in the east of the bay.