Litcius/Paper detail

Dissipating and reflecting internal waves

Callum J. Shakespeare, Brian K. Arbic, Andrew McC. Hogg

2021Journal of Physical Oceanography15 citationsDOI

Abstract

Abstract Internal waves generated at the seafloor propagate through the interior of the ocean, driving mixing where they break and dissipate. However, existing theories only describe these waves in two limiting cases. In one limit, the presence of an upper boundary permits bottom-generated waves to reflect from the ocean surface back to the seafloor, and all the energy flux is at discrete wavenumbers corresponding to resonant modes. In the other limit, waves are strongly dissipated such that they do not interact with the upper boundary and the energy flux is continuous over wavenumber. Here, a novel linear theory is developed for internal tides and lee waves that spans the parameter space in between these two limits. The linear theory is compared with a set of numerical simulations of internal tide and lee wave generation at realistic abyssal hill topography. The linear theory is able to replicate the spatially-averaged kinetic energy and dissipation of even highly non-linear wave fields in the numerical simulations via an appropriate choice of the linear dissipation operator, which represents turbulent wave breaking processes.

Topics & Concepts

Internal waveDissipationWavenumberPhysicsEnergy fluxGeophysicsTurbulenceMechanicsBoundary (topology)Breaking waveClassical mechanicsGeologyWave propagationOpticsMathematical analysisMathematicsThermodynamicsAstronomyOceanographic and Atmospheric ProcessesOcean Waves and Remote SensingTropical and Extratropical Cyclones Research