Litcius/Paper detail

Wave–Current Interactions at Meso- and Submesoscales: Insights from Idealized Numerical Simulations

Ana B. Villas Bôas, Bruce D. Cornuelle, Matthew R. Mazloff, Sarah T. Gille, Fabrice Ardhuin

2020Journal of Physical Oceanography50 citationsDOIOpen Access PDF

Abstract

Abstract Surface gravity waves play a major role in the exchange of momentum, heat, energy, and gases between the ocean and the atmosphere. The interaction between currents and waves can lead to variations in the wave direction, frequency, and amplitude. In the present work, we use an ensemble of synthetic currents to force the wave model WAVEWATCH III and assess the relative impact of current divergence and vorticity in modifying several properties of the waves, including direction, period, directional spreading, and significant wave height H s . We find that the spatial variability of H s is highly sensitive to the nature of the underlying current and that refraction is the main mechanism leading to gradients of H s . The results obtained using synthetic currents were used to interpret the response of surface waves to realistic currents by running an additional set of simulations using the llc4320 MITgcm output in the California Current region. Our findings suggest that wave parameters could be used to detect and characterize strong gradients in the velocity field, which is particularly relevant for the Surface Water and Ocean Topography (SWOT) satellite as well as several proposed satellite missions.

Topics & Concepts

Current (fluid)AmplitudeGeologyGeophysicsSurface waveOcean surface topographyOcean currentInternal waveRefractionVortexVorticityGravity waveWind waveMomentum (technical analysis)PhysicsWave propagationMechanicsGeodesyClimatologyOpticsFinanceEconomicsOceanographyOcean Waves and Remote SensingOceanographic and Atmospheric ProcessesCoastal and Marine Dynamics
Wave–Current Interactions at Meso- and Submesoscales: Insights from Idealized Numerical Simulations | Litcius