Entrainment and mixing of shelf/slope waters in the near‐surface Gulf Stream

An interdisciplinary study of the entrainment of shelf and slope waters in the Gulf Stream front was undertaken in October 1985 northeast of Cape Hatteras. Fifteen hydrographic transects of the Gulf Stream front and of the shelf water intrusion known as Ford water were completed in 2 1/2 days with a towed undulating profiler, the SeaSoar, equipped with a conductivity-temperature-depth probe and a fluorometer. Upstream sections within 50 km of the shelf break show entrainment of surface and subsurface waters along the northern edge of the high-velocity Gulf Stream. The low-salinity core, first observed at 70 m, is subducted to >100 m. The subsurface Ford water is also at a maximum in chlorophyll, fluorescence, and dissolved oxygen and contains a distinct diatom assemblage of nearshore species. Productivity rates in the Ford water may be equivalent to those in slope waters. Expendable current profilers yield an estimated transport for subsurface shelf waters of 1 to 5×105 m3 s−1 and indicate that vertical shear at the depth of maximum static stability is typically 2×10−2 s−1. A bulk Richardson number is estimated over vertical scales of several meters by combining SeaSoar density profiles with velocity shear from concurrent expendable current profiler deployments. The minimum values are generally >1, and only infrequently are they at or below the 0.25 threshold for shear instability. The presence of double-diffusive processes around the low-salinity core of Ford water is indicated by elevated conductivity Cox numbers. The stability parameter “Turner angle” shows that low-salinity Ford water and its associated T-S property front are sites of double-diffusive mixing, given general agreement between the distributions of Turner angle and Cox number. We conclude that double-diffusive processes are more important than shear flow instability in governing cross-isopycnal mixing. However, downstream transit times are so swift that no measurable change or decay occurs in the Ford water. This explains the occurrence of distinct shelf water phytoplankton species within the low-salinity waters downstream of Cape Hatteras.

[1]  Alvan. Fisher Entrainment of shelf water by the gulf stream northeast of Cape Hatteras , 1972 .

[2]  N. Garfield,et al.  Transport of low-salinity water at the slope water-Gulf Stream boundary , 1977 .

[3]  H. Stommel,et al.  The Gulf Stream : a physical and dynamical description , 1958 .

[4]  P. Falkowski,et al.  The fate of a spring phytoplankton bloom: export or oxidation? , 1988 .

[5]  C. Langdon,et al.  Seasonal variations in the phytoplankton biomass and productivity of a warm-core Gulf Stream ring , 1985 .

[6]  L. Pietrafesa,et al.  Observations of Gulf Stream-induced and wind-driven upwelling in the Georgia Bight using ocean color and infrared imagery , 1984 .

[7]  J. Walsh,et al.  The 1983-1984 Shelf Edge Exchange Processes (SEEP)--I experiment: hypotheses and highlights , 1988 .

[8]  R. Käse,et al.  Double Diffusion and the Distribution of the Density Ratio in the Mediterranean Waterfront Southeast of the Azores , 1987 .

[9]  M. Lewis,et al.  Vertical fluxes of nitrate associated with salt fingers in the world's oceans , 1989 .

[10]  J.-G. Dessureault,et al.  “Batfish” a depth controllable towed body for collecting oceanographic data☆ , 1976 .

[11]  James W. Brown,et al.  Satellite infrared observation of the kinematics of a warm-core ring , 1983 .

[12]  C. McClain,et al.  Role of Gulf Stream frontal eddies in forming phytoplankton patches on the outer southeastern shelf1 , 1981 .

[13]  Observations of small-scale shear and density structure in the ocean , 1982 .

[14]  Phytoplankton distribution along the eastern coast of the USA. Part II. Seasonal assemblages North of Cape Hatteras, North Carolina , 1978 .

[15]  A. Bower,et al.  The Gulf Stream—Barrier or Blender? , 1985 .

[16]  Amy S. Bower,et al.  Evidence of Cross-Frontal Exchange Processes in the Gulf Stream Based on Isopycnal RAFOS Float Data , 1989 .

[17]  J. McKENZIE,et al.  Thermohaline intrusions lie across isopycnals , 1979, Nature.

[18]  A. Williams The role of double diffusion in a Gulf Stream frontal intrusion , 1981 .

[19]  B. Ruddick A Practical Indicator of the Stability of the Water Column to Double-Diffusive Activity , 1983 .

[20]  Timothy R. Parsons,et al.  A manual of chemical and biological methods for seawater analysis , 1984 .

[21]  P. Hamilton,et al.  Circulation of slopewater , 1988 .

[22]  R. Schmitt Finestructure and microstructure in the North Atlantic Current , 1982 .

[23]  R. Schmitt,et al.  Fine- and microstructure at the edge of a warm-core ring , 1986 .

[24]  P. Hamilton,et al.  Velocity and hydrographic structure of subsurface shelf water at the Gulf Stream's edge , 1989 .

[25]  David L. Evans,et al.  Shelf water entrainment by Gulf Stream warm-core rings , 1987 .