Evolution of Oceanic Near-Surface Stratification in Response to an Autumn Storm

• Published in: Journal of physical oceanography Vol. 49; no. 11; pp. 2961 - 2978
• Main Authors: Lucas, Natasha S., Grant, Alan L. M., Rippeth, Tom P., Polton, Jeff A., Palmer, Matthew R., Brannigan, Liam, Belcher, Stephen E.
• Format: Journal Article
• Language: English
• Published: Boston American Meteorological Society 01.11.2019
• Subjects: Aerodynamics; Air-sea flux; Autumn storms; Boundary layer; Boundary layers; Computer simulation; Diapycnal mixing; Energy; Evolution; Gases; Heat budget; Inertial currents; Kinetic energy; Langmuir circulation; Langmuir turbulence; Large eddy simulation; Large eddy simulations; Momentum; Momentum balance; Ocean surface; Oceanic eddies; Oceanic mixed layer; Oceans; Osmosis; Parameterization; Profiles; Salinity; Sensors; Spikes; Standard deviation; Storms; Stratification; Surface boundary layer; Thermocline; Trace gases; Transition layers; Turbulence; Turbulent kinetic energy; Wind; Wind shear
• ISSN: 0022-3670; 1520-0485; 1520-0485
• DOI: 10.1175/JPO-D-19-0007.1

Abstract Understanding the processes that control the evolution of the ocean surface boundary layer (OSBL) is a prerequisite for obtaining accurate simulations of air–sea fluxes of heat and trace gases. Observations of the rate of dissipation of turbulent kinetic energy ( ε ), temperature, salinity, current structure, and wave field over a period of 9.5 days in the northeast Atlantic during the Ocean Surface Mixing, Ocean Submesoscale Interaction Study (OSMOSIS) are presented. The focus of this study is a storm that passed over the observational area during this period. The profiles of ε in the OSBL are consistent with profiles from large-eddy simulation (LES) of Langmuir turbulence. In the transition layer (TL), at the base of the OSBL, ε was found to vary periodically at the local inertial frequency. A simple bulk model of the OSBL and a parameterization of shear driven turbulence in the TL are developed. The parameterization of ε is based on assumptions about the momentum balance of the OSBL and shear across the TL. The predicted rate of deepening, heat budget, and the inertial currents in the OSBL were in good agreement with the observations, as is the agreement between the observed value of ε and that predicted using the parameterization. A previous study reported spikes of elevated dissipation related to enhanced wind shear alignment at the base of the OSBL after this storm. The spikes in dissipation are not predicted by this new parameterization, implying that they are not an important source of dissipation during the storm.