Sea surface height relations from mesoscale to submesoscale

Gregg Arthur Jacobs, Naval Research Lab Stennis Space Center, Stennis Space Center, MS, United States
Abstract:
The Surface Water / Ocean Topography (SWOT) mission will change our perceptions of the ocean, and this can be shown by examining how sea surface height (SSH) has been used in the past, the processes expected to be observed by SWOT and the different dynamical relations. This motivates understanding the implication of the SWOT data in the domain of previously unresolved ocean features. Historically, because of the relatively sparse spatial sampling, SSH observations have been related to mesoscale eddy circulations in the ocean. To first order, mesoscale eddies are in geostrophic and hydrostatic balance. This understanding has enabled mesoscale ocean predictions from global scales such as the Global Ocean Forecast System (GOFS) to the reloctable forecast system (RELO) to the coupled ocean / atmosphere mesoscale prediction system (COAMPS). SWOT will reveal submesoscale eddies that are not in geostrophic balance, and their vertical extent is mainly in the mixed layer rather than to the deep thermocline. High resolution model experiments are used to estimate relationships between the surface height signatures and subsurface structures due to mesoscale and submesoscale eddies, both of which produce clear expressions in the mixed layer depth (figure below). The results from a 1 km resolution ocean model covering the Gulf of Mexico provide the 3D structure representing both mesoscale and submesoscale to begin to understand the correlations throughout the water column. The initial examinations provide insight to the relation between SSH and its spatial gradients to the underlying temperature, salinity and velocity structure within the mixed layer and at the deeper thermocline depths. The model-derived SSH correlations at the thermocline depth and within the mixed layer can lend insight to horizontal length scales to classify mesoscale and submesocale features.