Simulation and analysis of marine hydrodynamics based on the El Niño scenario

IF 3.1 Q2 ENVIRONMENTAL SCIENCES
M. Ikhwan, R. Wafdan, Y. Haditiar, M. Ramli, Z. Muchlisin, S. Rizal
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引用次数: 0

Abstract

BACKGROUND AND OBJECTIVES: El Nino - Southern Oscillation is known to affect the marine and terrestrial environment in Southeast Asia, Australia, northern South America, and southern Africa. There has been much research showing that the effects of El Nino - Southern Oscillation are extensive. In this study, a simulation of an El Nino event is carried out, which is ideal in the vertical layer of the Pacific Ocean (0-250 meters). The fast Fourier transform is used to process the vertical modeling data so that the results can accurately represent El Nino. METHODS: A non-hydrostatic 3-dimensional numerical model is used in this research. To separate the signal produced and obtain the quantitative difference of each sea layer, the simulation results are analyzed using the fast Fourier transform. Winds blow from the west to the east of the area in perfect El Nino weather, with a reasonably high wind zone near the equator (forming a cosine). Open fields can be found on the north and south sides, while closed fields can be found on the west and east sides. Density is uniform up to a depth of 100 meters, then uniformly increases by 1 kilogram per cubic meter from 100 to 250 meters.  FINDINGS: The results of the model simulation show that one month later (on the 37th day), the current from the west has approached the domain's east side, forming a complete coastal Kelvin wave. The shape of coastal Kelvin waves in the eastern area follows a trend that is similar to the OSCAR Sea Surface Velocity plot data obtained from ERDDAP in the Pacific Ocean in October 2015. In this period, the density at a depth of 0-100 meters is the same, while the density at the depth layer underneath is different.  CONCLUSION: Strong winds could mix water masses up to a depth of 100 meters, implying that during an ideal El Nino, the stratification of the water column is influenced by strong winds. The eastern domain has the highest sea level amplitude, resulting in perfect mixing up to a depth of 100 m, while wind effect is negligible in the lower layers. The first layer (0-50 m) and the second layer (50-100 m) have the same density and occur along the equator, according to FFT. The density is different and much greater in the third layer (100-150 m).
基于厄尔尼诺情景的海洋流体动力学模拟与分析
背景和目标:众所周知,厄尔尼诺-南方涛动会影响东南亚、澳大利亚、南美洲北部和非洲南部的海洋和陆地环境。已有大量研究表明,厄尔尼诺-南方涛动的影响是广泛的。在这项研究中,对厄尔尼诺事件进行了模拟,这在太平洋垂直层(0-250米)是理想的。采用快速傅立叶变换对垂直建模数据进行处理,使结果能够准确地表示厄尔尼诺现象。方法:采用非静力三维数值模型。为了分离产生的信号并获得每个海洋层的定量差异,使用快速傅立叶变换对模拟结果进行分析。在完美的厄尔尼诺天气中,风从该地区的西部吹向东部,赤道附近有一个相当高的风区(形成余弦)。在北侧和南侧可以找到开阔的田地,而在西侧和东侧可以找到封闭的田地。密度在100米深的地方是均匀的,然后从100米到250米每立方米均匀增加1公斤。结果:模型模拟的结果显示,一个月后(第37天),来自西部的洋流已经接近该地区的东侧,形成了一个完整的沿海开尔文波。东部地区沿海Kelvin波的形状与2015年10月从太平洋ERDDAP获得的OSCAR海面速度图数据相似。在这一时期,0-100米深处的密度是相同的,而下面深层的密度不同。结论:强风可以混合100米深的水团,这意味着在理想的厄尔尼诺现象中,水柱的分层受到强风的影响。东部地区的海平面振幅最高,导致100米深度的完美混合,而较低层的风效应可以忽略不计。根据FFT,第一层(0-50m)和第二层(50-100m)具有相同的密度并且沿着赤道出现。密度不同,并且在第三层(100-150米)中要大得多。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
7.90
自引率
2.90%
发文量
11
审稿时长
8 weeks
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