Downwelling in Basins Subject to Buoyancy Loss

• Published in: Journal of physical oceanography Vol. 42; no. 11; pp. 1817 - 1833
• Main Author: Cenedese, Claudia
• Format: Journal Article
• Language: English
• Published: Boston, MA American Meteorological Society 01.11.2012
• Subjects: Atmosphere; Boundary currents; Boundary layers; Buoyancy; Climate models; Convection; Deformation; Downwelling; Earth, ocean, space; Eddies; Exact sciences and technology; Experiments; External geophysics; Field tests; Heat; Laboratories; Marine; Measurement techniques; Meteorology; Mixing; Mixing processes; Oceanography; Physics of the oceans; Plumes; Sea currents; Studies; Temperature; Thermohaline circulation; Thermohaline structure and circulation. Turbulence and diffusion; Thickness; Turbulent mixing; Velocity; Vertical velocities; Viscosity; Nordic Seas; United States > US; Labrador Sea; Atlantic Ocean; ANE, Norwegian Sea, Lofoten Basin; ANW, Labrador Sea; downwelling; Laboratory study; Boundary current; thermohaline circulation; buoyancy; ocean circulation; Turbulent mixing
• ISSN: 0022-3670; 1520-0485
• DOI: 10.1175/JPO-D-11-0114.1

Recent observational, theoretical, and modeling studies all suggest that the upper part of the downwelling limb of the thermohaline circulation is concentrated in strong currents subject to buoyancy loss near lateral boundaries. This is fundamentally different from the traditional view that downwelling takes place in regions of deep convection. Even when resolving the buoyant boundary currents, coarse-resolution global circulation and climate models rely on parameterizations of poorly known turbulent mixing processes. In this study, the first direct measurements of downwelling occurring within a basin subject to buoyancy loss are obtained. Downwelling is observed near the basin’s vertical wall within the buoyant boundary current flowing cyclonically around the basin. Although the entire basin is cooled, large-scale mean downwelling is absent in the basin interior. Laboratory rotating experiments are conducted to explicitly resolve the turbulent mixing due to convective plumes and the baroclinic eddies generated by the boundary current, and to identify where downwelling takes place. Small vertical velocities can be measured more reliably in the laboratory than in many numerical calculations, whereas the measurement of these small vertical velocities is still a challenge for field experiments. Downwelling is observed near the vertical wall within a boundary layer with a thickness that scales with the baroclinic Rossby radius of deformation, consistent with the dynamical balance proposed by a previous numerical study. Hence, downwelling in the Labrador Sea and Lofoten Basin cyclonic boundary currents may be concentrated in a baroclinic Rossby radius of deformation thick boundary layer in regions with large eddy generation.