Reduction of the usable wind-work on the general circulation by forced symmetric instability

• Published in: Geophysical research letters Vol. 37; no. 18
• Main Authors: Thomas, L. N., Taylor, J. R.
• Format: Journal Article
• Language: English
• Published: Washington, DC Blackwell Publishing Ltd 01.09.2010; American Geophysical Union; John Wiley & Sons, Inc
• Subjects: Buoyancy; Earth sciences; Earth, ocean, space; energetics of the circulation; Exact sciences and technology; fronts; Kinetic energy; Ocean circulation; Physical oceanography; submesoscale processes; Water circulation; Wind; orientation; kinetic energy; shear; Potential vorticity; Wind effect; digital simulation; transport; velocity; buoyancy; Mixed layer; winds; instability; Three dimensional turbulence; Geostrophic flow; reduction; ocean circulation; Geostrophic current; high resolution
• ISSN: 0094-8276; 1944-8007
• DOI: 10.1029/2010GL044680

Winds aligned with geostrophic currents input energy into the ocean circulation. For baroclinic, surface‐intensified currents, winds of this orientation (i.e., down‐front winds) reduce the potential vorticity in the mixed layer, making the flow susceptible to symmetric instability (SI). SI is a submesoscale shear instability that draws its energy from baroclinic, geostrophic currents. High‐resolution numerical simulations are used to demonstrate how forced SI driven by down‐front winds extracts energy from the geostrophic flow at a rate proportional to the Ekman buoyancy flux, the dot product of the Ekman transport and the surface buoyancy gradient. The kinetic energy (KE) going into SI is converted to 3D turbulence through a secondary shear instability and ultimately dissipated at small scales. Thus under the conditions where winds input KE to the circulation, some of the KE of baroclinic currents is dissipated by this mechanism. The net result of this submesoscale sink of KE is to reduce the usable wind‐work, i.e., the wind‐induced rate of KE increase, by an amount that depends on the wind‐stress and the change in geostrophic velocity across the mixed layer.