Cc. Chen et al., A NUMERICAL STUDY OF STRATIFIED TIDAL RECTIFICATION OVER FINITE-AMPLITUDE BANKS .2. GEORGES-BANK, Journal of physical oceanography, 25(9), 1995, pp. 2111-2128
Tidal rectification over an idealized two-dimensional cross section of
Georges Bank, which is a large, shallow, elongated submarine bank in
the Gulf of Maine, is studied using a primitive equation coastal ocean
circulation model. In the homogeneous case, the model predicts a topo
graphically controlled residual circulation over Georges Bank, flowing
northeastward as a strong jet with a maximum speed of about 16 cm s(-
1) along the northern flank and southwestward as a relatively weak and
broad flow with a maximum speed of about 3 cm s(-1) on the southern f
lank. As stratification is added, tidal rectification and tidal mixing
intensify the along- and cross-isobath residual currents and create t
idal fronts. During summer, the tidal fronts are located at the 40-m i
sobath on the northern flank and at the 50-60-m isobath on the souther
n flank, while during winter, the position of the tidal front remains
fixed on the northern flank; however, it moves to the shelf break on t
he southern flank. The summer and winter maxima of the along-bank curr
ent are about 32 cm s(-1) and 26 cm s(-1) on the northern flank and 8
cm s(-1) and 6 cm s(-1) on the southern flank, respectively. The model
results are in reasonable agreement with observations. The summertime
intensification of the residual flow is mainly due to nonlinear inter
action between the stratified tidal currents over the northern flank w
ith the steep bottom topography there and to the baroclinic density gr
adient created in part by tidal mixing over the southern flank where t
he bottom slope is smaller.