Numerical Investigation of Currents on Georges Bank
INVESTIGATORS:
Benoit Cushman-Roisin
Thayer School of Engineering
Dartmouth College
Hanover, NH 03755
(603)646-3844
(603)646-3856 fax
B.Cushman@Dartmouth.EDU
Daniel R. Lynch
Thayer School of Engineering
Dartmouth College
Hanover, NH 03755
(603)646-2308
(603)646-3856 fax
Daniel.R.Lynch@Dartmouth.EDU
GRANT PERIOD: July 1, 1993 - June 30, 1996
STATEMENT OF OBJECTIVES:
The recent collapse and closure of the Georges Bank fishery highlights
the impact environmental variability can have on fish populations,
especially populations already under intense fishing pressure. On
Georges Bank, recruitment of young fish is critically dependent on the
highly variable currents acting to keep eggs and larvae on the bank. In
years when the currents sweep many eggs and larvae off the bank,
recruitment is very poor. A few consecutive years of low recruitment can
cause a fish population to crash, at tremendous ecological and social
cost.
We use a three-dimensional finite-element coastal ocean numerical model
developed at Dartmouth College to model the critical current system on
the southern flank of Georges Bank. The currents on Georges Bank are
largely controlled by five external factors: density differences between
continental shelf and continental slope waters, tides which resonate in
the Gulf of Maine, summer heating, seasonal winds, and episodic events
such as strong storms and Gulf Stream rings. Taken together these
forcings create a variable and complex current system on the bank. Our
approach is to break this complex system into its fundamental components
and then rebuild the complex current system block by block, at each step
analyzing the effects of the latest block on the system as a whole. In
analyzing the current system at each stage we ask several important
questions:
- What is the dynamical composition of the current as a function of
both position and time?
- What is the structure of the flow in the vertical and cross-stream
directions?
- What are the possible instabilities?
- And, what are the possibilities for water exchange across the current
system?
STATEMENT OF WORK:
We have created a finite-element mesh of more than 13,000 nodes and
25,000 triangular elements to cover the Gulf of Maine/Georges Bank area.
Mesh resolution is less than 1km in critical areas, and no element has
greater than a 30% change in depth among its nodes. Runs of the model
for the first steps of the study show a large influence on the currents
by the steep bottom topography along the sides of Georges Bank. The
sharp change from the relatively flat bank top to the steep bank sides
creates an area of vertical mixing known as the shelf break front. This
front creates a partition in the water that tends to keep eggs and
larvae from being swept off the bank. In addition, the runs for the
first steps highlight the importance of an area where the currents turn
into the Great South Channel. Here, the currents split, with one part
turning to wrap around back to the North that keeps young fish on the
bank, and the other part turning to the South that sweeps young fish
into the deep water of the Mid-Atlantic Bight.
We are in the process of making more complex simulations with the model.
These runs include the tides, seasonal heating and seasonal winds. Tidal
resonance in the Gulf of Maine produces a strong clockwise residual flow
around Georges Bank. Combined with tidal mixing, seasonal heating
produces a tidal mixing front on the bank top. This front separates well
mixed shallow regions on the bank top from the stratified deeper regions
of the bank sides. Both the clockwise flow and the tidal mixing front
effects serve to help keep young fish on the bank.
The coastal ocean model as well as the finite element mesh used for this
study will be available on the World Wide Web via a home page dedicated
to coastal and climate change research conducted at Dartmouth.
SUMMARY OF KEY FINDINGS:
Simulations to date show that the currents on Georges Bank are largely
controlled by the steep and complex topography. As currents climb up or
down slopes they are vertically squeezed or stretched. Because of the
earth's rotation, this stretching or squeezing causes the currents to
turn to left or the right, respectively. This is the critical factor
that causes the along shelf jet on the southern flank to veer into the
Great South Channel and then turn South again to continue into the
Mid-Atlantic Bight. The topography also affects the currents through
friction with the sea floor. This bottom friction tends to slow down
currents in shallow regions and reduces the turning effects of the
earth's rotation. In addition, bottom friction creates boundary layers
where the water behaves differently than it does above. Preliminary
numerical as well as early analytical results show that these effects
are very important to the fate of young fish on Georges Bank.
In addition to offering important insights into the dynamics of the
currents on Georges Bank, this study provides a test for the powerful
new three-dimensional finite-element coastal ocean model developed at
Dartmouth. The success the model has had in simulating currents for a
variety of cases in the difficult Gulf of Maine-Georges Bank system
shows that it is a robust tool that will be useful in studies of other
coastal areas, as well as future, more detailed studies of Georges Bank.
REFERENCES:
Lynch, D.R., J.T.C. Ip, C.E. Naimie, F.E. Werner, 1995: Comprehensive
Coastal Circulation Model with Application to the Gulf of Maine.
Continental Shelf Research, in press