Internal Tides in the Coastal Waters of NE Arabian Sea: Observations and Simulations

Time series of temperature and salinity collected from a station in the NE Arabian Sea during March, April, May, October, and November was utilized to explain the behavior of internal tides. Analysis revealed the existence of semi-diurnal internal tides and high frequency (HF) internal waves (IW). I...

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Bibliographic Details
Published in:Marine geodesy 2010-04, Vol.33 (2-3), p.232-244
Main Authors: Kumar, P. V. Hareesh, Lekshmi, S., Jagadeesh, P. S. V., Anilkumar, K., Krishnakumar, G. V., Rao, A. D.
Format: Article
Language:English
Subjects:
Coasts
coupled model
Geodetics
Internal tides
Marine
one-dimensional and internal wave model
Regression analysis
Simulation
Temperature
Tides
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Summary:Time series of temperature and salinity collected from a station in the NE Arabian Sea during March, April, May, October, and November was utilized to explain the behavior of internal tides. Analysis revealed the existence of semi-diurnal internal tides and high frequency (HF) internal waves (IW). It was observed that the amplitudes of HF IWs were determined by the degree of stratification in the thermocline. Corresponding to an increase in the density gradient in thermocline (0.016 kg/m 4 in April to 0.14 kg/m 4 in October), the temperature fluctuations due to internal tides increased from 1.5°C, respectively. Brunt-Vaiisala frequency also showed similar variations (∼10 cph to 22 cph). Within the thermocline, semi-diurnal internal tides caused fluctuations of >10m in the isotherm depths. A linear regression equation was fitted to parameterize the amplitude of HF IWs and its upper frequency limit in terms of thermocline gradient. The IW and one-dimensional models simulated the presence of internal tides and diurnal cycling in the temperature field, respectively. Coupling of these models showed improvement in the simulation of temperature.
ISSN:0149-0419
1521-060X
DOI:10.1080/01490419.2010.493494