{"title":"未来索那达海风暴潮研究","authors":"Ayano Sonoda","doi":"10.2208/kaigan.75.i_1183","DOIUrl":null,"url":null,"abstract":"Japan lies on an area frequently hit by typhoons while city functions are clustered along the flat coastal areas, hence Japan has experienced lots of storm surge disasters up to the present. Coastal areas along the Suo-nada Sea also have the vulnerability against storm surge and in the past Typhoon 18 in 1999, Typhoon 16 and 18 in 2004 made remarkable damages in the areas. Furthermore, due to global warming, there are growing concerns about possible tremendous storm surge disasters caused by more furious typhoons than ever. Thus it is necessary to estimate the future storm surge for the coastal disaster prevention. The Suo-nada Sea, however, has some topographical factors which make storm surge estimations difficult. In this study, numerical simulations for storm surge around the Suo-nada Sea were performed by using a coastal circulation model FVCOM (Finite Volume Coastal Ocean Model) developed by Chen et al. (2003). FVCOM employs an unstructured grid system so as to accurately compute tidal currents even in complicated inner bays. First, appropriate computational domain was investigated. Then influences of various input data; calculation results by an empirical typhoon model, simulation results by a regional meteorological model and Grid Point Value, on the accuracy of simulations were examined. Next, future changes of typhoon characteristics around the sea area was investigated on the basis of Database for Policy Decision making for Future climate change (d4PDF). Finally, the future storm surge in Suo-nada Sea was estimated. 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引用次数: 0
摘要
日本地处台风多发地区,而城市功能又集中在平坦的沿海地区,因此迄今为止日本经历了许多风暴潮灾害。索纳达海沿岸地区也具有风暴潮的易损性,在过去的1999年18号台风、2004年16号台风和18号台风对该地区造成了显著的破坏。此外,由于全球变暖,越来越多的人担心,比以往任何时候都更猛烈的台风可能会造成巨大的风暴潮灾害。因此,对未来风暴潮进行预估对于沿海灾害的预防是十分必要的。然而,索纳达海有一些地形因素,使风暴潮的估计困难。本研究采用Chen et al.(2003)开发的沿海环流模式FVCOM (Finite Volume coastal Ocean model,有限体积沿海海洋模型)对索纳达海附近风暴潮进行了数值模拟。FVCOM采用非结构化网格系统,即使在复杂的内湾也能准确计算潮流。首先,研究了合适的计算域。然后是各种输入数据的影响;比较了经验台风模式的计算结果、区域气象模式的模拟结果和网格点值对模拟精度的影响。其次,基于未来气候变化政策决策数据库(d4PDF),研究了周边海域台风特征的未来变化。最后,对未来索纳达海风暴潮进行了预测。模拟结果表明,受全球变暖的影响,未来将有更多的强台风袭击南海,台风路径将向北移动。这也表明,未来海域周边风暴潮可能会更加发达,对周边地区造成更严重的破坏。(少)
Japan lies on an area frequently hit by typhoons while city functions are clustered along the flat coastal areas, hence Japan has experienced lots of storm surge disasters up to the present. Coastal areas along the Suo-nada Sea also have the vulnerability against storm surge and in the past Typhoon 18 in 1999, Typhoon 16 and 18 in 2004 made remarkable damages in the areas. Furthermore, due to global warming, there are growing concerns about possible tremendous storm surge disasters caused by more furious typhoons than ever. Thus it is necessary to estimate the future storm surge for the coastal disaster prevention. The Suo-nada Sea, however, has some topographical factors which make storm surge estimations difficult. In this study, numerical simulations for storm surge around the Suo-nada Sea were performed by using a coastal circulation model FVCOM (Finite Volume Coastal Ocean Model) developed by Chen et al. (2003). FVCOM employs an unstructured grid system so as to accurately compute tidal currents even in complicated inner bays. First, appropriate computational domain was investigated. Then influences of various input data; calculation results by an empirical typhoon model, simulation results by a regional meteorological model and Grid Point Value, on the accuracy of simulations were examined. Next, future changes of typhoon characteristics around the sea area was investigated on the basis of Database for Policy Decision making for Future climate change (d4PDF). Finally, the future storm surge in Suo-nada Sea was estimated. From the simulations, it was found that more intense typhoons would strike the Suo-nada Sea and the direction of typhoon tracks would change toward the north in the future due to the global warming. It was also shown that the storm surge around the sea area can be more developed and cause more severe damages around the region in the future. (Less)
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