论文信息 - Free surface, current profile and buoyancy effects upon internal wave energy flux profiles in sill regions

Free surface, current profile and buoyancy effects upon internal wave energy flux profiles in sill regions

A non-hydrostatic ocean circulation model is used to determine the distribution of the horizontal energy flux terms due to internal waves in sill regions. Calculations show that although the linear energy flux term is significant, the contribution from the non-linear terms is appreciable. In addition, unlike as is often assumed in deep ocean situations, the free surface contribution to the energy flux distribution often dominates. The magnitude and relative importance of the energy flux terms are influenced by how the fluctuating velocity due to internal waves is computed. In addition changes in vertical stratification affects the relative contribution of the energy flux terms although the free surface term still dominates.

Jarle Berntsen | Alan M. Davies | Jiuxing Xing

[1] R. Greatbatch,et al. Enhanced vertical propagation of storm‐induced near‐inertial energy in an eddying ocean channel model , 2005 .

[2] J. Nash,et al. Estimating Internal Wave Energy Fluxes in the Ocean , 2005 .

[3] M. J. Howarth,et al. Enhanced stability during reduction of stratification in the North Sea , 2004 .

[4] A. M. Davies,et al. Processes influencing tidal mixing in the region of sills , 2006 .

[5] A. M. Davies,et al. Influence of stratification and topography upon internal wave spectra in the region of sills , 2006 .

[6] J. Nash,et al. Energy Transport by Nonlinear Internal Waves , 2007 .

[7] H. Haren,et al. Near-bed solibores over the continental slope in the Faeroe-Shetland Channel , 2004 .

[8] M. Inall,et al. Evolution and distribution of TKE production and dissipation within stratified flow over topography , 2005 .

[9] L. Perelman,et al. Hydrostatic, quasi‐hydrostatic, and nonhydrostatic ocean modeling , 1997 .

[10] F. Cottier,et al. Sill dynamics and energy transformation in a jet fjord , 2004 .

[11] O. Fringer,et al. Nonhydrostatic and nonlinear contributions to the energy flux budget in nonlinear internal waves , 2005 .