nerc.ac.uk

Non-hydrostatic and non-linear contributions to the internal wave energy flux in sill regions

Davies, Alan M.; Xing, Jiuxing; Berntsen, Jarle. 2009 Non-hydrostatic and non-linear contributions to the internal wave energy flux in sill regions. Ocean Dynamics, 59 (6). 881-897. 10.1007/s10236-009-0217-2

Full text not available from this repository. (Request a copy)

Abstract/Summary

A three-dimensional non-linear, non-hydrostatic model in cross-sectional form is used to determine the factors influencing the relative importance of the linear, non-hydrostatic and non-linear contributions to the internal wave energy flux in sill regions due to tidal forcing. The importance of the free surface elevation term is also considered. Idealised topography representing the sill at the entrance to Loch Etive, the site of a recent measurement programme, is used. Calculations show that the non-linear terms in the energy flux become increasingly important as the sill Froude Number (F (s)) increases and the sill aspect ratio is increased. The vertical profile of the stratification, in particular its value close to the sill crest where internal waves are generated, has a significant influence on unsteady lee wave and mixed tidal-lee wave generation and the non-linear contribution to the energy flux. Calculations show that as F (s) increases, the energy flux due to the non-linear and non-hydrostatic terms increases more rapidly than the linear term. The importance of the non-linear terms in the energy flux also increases as the sill aspect ratio is increased. Increasing the buoyancy frequency reduces the contribution of the non-hydrostatic and non-linear terms to the total energy flux. Also, as the buoyancy frequency is increased, this reduces unsteady lee wave and mixed tidal-lee wave generation. In essence, these calculations show that the energy flux due to the non-hydrostatic and non-linear terms is appreciable in sill regions.

Item Type: Publication - Article
Digital Object Identifier (DOI): 10.1007/s10236-009-0217-2
Programmes: Oceans 2025 > Next generation ocean prediction systems
ISSN: 1616-7341
Additional Keywords: Non-hydrostatic; Energy flux; Sill; Lee waves; Internal tide TIDAL FLOW; STRATIFIED FLOW; KNIGHT INLET; FORM DRAG; TOPOGRAPHY; OCEAN; GENERATION; SEPARATION; MECHANISM; CHANNEL
NORA Subject Terms: Marine Sciences
Date made live: 23 Jun 2010 12:21 +0 (UTC)
URI: https://nora.nerc.ac.uk/id/eprint/9705

Actions (login required)

View Item View Item

Document Downloads

Downloads for past 30 days

Downloads per month over past year

More statistics for this item...