TURBULENT MIXING UNDER DRIFTING PACK ICE IN THE WEDDELL SEA

By providing cold, dense water that sinks and mixes to fill the abyssa l world ocean, high-latitude air-sea-ice interaction is the main condu it through which the deep ocean communicates with the rest of the clim ate system. A key element in modeling and predicting oceanic impact on climate is understanding the processes that control the near surface exchange of heat, salt, and momentum. In 1992, the United States-Russi an Ice Station Weddell-1 traversed the western Weddell Sea during the onset of winter, providing a platform for direct measurement of turbul ent heat flux and Reynolds stress in the upper ocean. Data from a stor m early in the drift indicated (i) well-formed Ekman spirals (in both velocity and turbulent stress); (ii) high correlation between mixed la yer heat flux and temperature gradients; (iii) that eddy viscosity and eddy thermal diffusivity were similar, about 0.02 square meters per s econd; and (iv) that the significant turbulent length scale (2 to 3 me ters through most of the boundary layer) was proportional to the wavel ength at the peak in the weighted vertical velocity spectrum. The meas urements were consistent with a simple model in which the bulk eddy vi scosity in the neutrally buoyant mixed layer is proportional to kinema tic boundary stress divided by the Coriolis parameter.