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Near-Inertial Waves and Turbulence Driven by the Growth of Swell

Gregory LeClaire Wagner, Gregory P. Chini, Ali Ramadhan, Basile Gallet, Raffaele Ferrari

2021Journal of Physical Oceanography10 citationsDOIOpen Access PDF

Abstract

Abstract Between 5% and 25% of the total momentum transferred between the atmosphere and ocean is transmitted via the growth of long surface gravity waves called “swell.” In this paper, we use large-eddy simulations to show that swell-transmitted momentum excites near-inertial waves and drives turbulent mixing that deepens a rotating, stratified, turbulent ocean surface boundary layer. We find that swell-transmitted currents are less effective at producing turbulence and mixing the boundary layer than currents driven by an effective surface stress. Overall, however, the differences between swell-driven and surface-stress-driven boundary layers are relatively minor. In consequence, our results corroborate assumptions made in Earth system models that neglect the vertical structure of swell-transmitted momentum fluxes and instead parameterize all air–sea momentum transfer processes with an effective surface stress.

Topics & Concepts

SwellTurbulenceInertial waveMomentum (technical analysis)MechanicsBoundary layerMomentum transferGeologyWind waveAdvectionWind stressGeophysicsMixing (physics)MeteorologyPhysicsAtmospheric sciencesWave propagationMechanical waveOpticsOceanographyLongitudinal waveQuantum mechanicsThermodynamicsFinanceEconomicsScatteringOcean Waves and Remote SensingOceanographic and Atmospheric ProcessesAeolian processes and effects