Three-dimensional numerical simulation of internal tides that radiated from the Luzon Strait into the Western Pacific

Recent satellite altimeter observations have indicated that internal tides (ITs) from the Luzon Strait (LS) propagate more than 2 500 km into the Western Pacific (WP). This study used a high-resolution three-dimensional numerical model to reproduce and examine the ITs radiation process. The propagat...

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Bibliographic Details
Published inChinese journal of oceanology and limnology Vol. 35; no. 6; pp. 1275 - 1286
Main Author 刘昆;徐振华;尹宝树
Format Journal Article
LanguageEnglish
Published Heidelberg Science Press 01.11.2017
Springer Nature B.V
Subjects
Abyssal zone
Altimeters
Computer simulation
Decay rate
Diurnal
Diurnal variations
Earth
Earth and Environmental Science
Earth rotation
Earth Sciences
Energy
energy flow
Energy transfer
Equator
Internal tides
Latitude
Mathematical analysis
Mathematical models
Numerical analysis
Numerical models
Oceanography
Phase velocity
Philippines
Physics
Propagation
Radiation
Rotation
Satellite observation
Satellites
Simulation
Three dimensional models
Tidal dynamics
Tidal waves
Tides
Wave propagation
Wavelength
wavelengths
Width
三维数值模式
三维数值模拟
传播过程
内潮
卫星高度计
吕宋海峡
西太平洋
辐射过程
Luzon
Pacific Ocean
Philippines
internal tides
Luzon Strait
numerical simulation
Western Pacific
Online AccessGet full text
ISSN0254-4059
2096-5508
1993-5005
2523-3521
DOI10.1007/s00343-017-5376-2

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Summary:Recent satellite altimeter observations have indicated that internal tides (ITs) from the Luzon Strait (LS) propagate more than 2 500 km into the Western Pacific (WP). This study used a high-resolution three-dimensional numerical model to reproduce and examine the ITs radiation process. The propagation of diurnal and semidiurnal ITs showed different patterns and variations. Diurnal ITs with lower frequency were affected more by the earth's rotation and they were bent more toward the equator than semidiurnal ITs. ITs phase speeds are functions of latitude and diurnal ITs showed greater distinctions of phase speeds during propagation. For M2 ITs, the wavelength remained nearly unchanged but the beam width increased significantly during propagation away from the LS. For diurnal ITs (K1 and O0, the wavelength decreased noticeably with latitude, while the beam width varied little during propagation because of blocking by land. Baroclinic energy was also examined as a complement to satellite results reported by Zhao (2014). The magnitude of the generated baroclinic energy flux reduced remarkably within 300 km from the generation site but it then decayed slowly when propagating into abyssal sea. Baroclinic energy of diurnal ITs was found to dissipate at a slower rate than semidiurnal ITs along the main propagation path in the WP.
Bibliography:LIU Kun 1, 2, 4, XU Zhenhua 1, 2, 3, YIN Baoshu 1, 2,3 (1Institute of Oceanology, Chinese Academy of Sciences, Qingdao 266071, China ;2 Key Laboratory of Ocean Circulation and Waves (KLOCAW), Chinese Academy of Sciences, Qingdao 266071, China; 3 Laboratory for Ocean and Climate Dynamics, Qingdao National Laboratory for Marine Science and Technology, Qingdao 266071, China;4University of Chinese Academy of Sciences, Beijing 100049, China)
internal tides; numerical simulation; Luzon Strait; Western Pacific
Recent satellite altimeter observations have indicated that internal tides (ITs) from the Luzon Strait (LS) propagate more than 2 500 km into the Western Pacific (WP). This study used a high-resolution three-dimensional numerical model to reproduce and examine the ITs radiation process. The propagation of diurnal and semidiurnal ITs showed different patterns and variations. Diurnal ITs with lower frequency were affected more by the earth's rotation and they were bent more toward the equator than semidiurnal ITs. ITs phase speeds are functions of latitude and diurnal ITs showed greater distinctions of phase speeds during propagation. For M2 ITs, the wavelength remained nearly unchanged but the beam width increased significantly during propagation away from the LS. For diurnal ITs (K1 and O0, the wavelength decreased noticeably with latitude, while the beam width varied little during propagation because of blocking by land. Baroclinic energy was also examined as a complement to satellite results reported by Zhao (2014). The magnitude of the generated baroclinic energy flux reduced remarkably within 300 km from the generation site but it then decayed slowly when propagating into abyssal sea. Baroclinic energy of diurnal ITs was found to dissipate at a slower rate than semidiurnal ITs along the main propagation path in the WP.
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ISSN:0254-4059
2096-5508
1993-5005
2523-3521
DOI:10.1007/s00343-017-5376-2