1. Shelf Break Fronts: How much do we really know
Shelf Break Fronts: How much do we really know? A brief overview of the physical properties, formation and modeling of Shelf Break Fronts
LT Thomas B. Keefer

2. Shelf Break Fronts: What are they?
LT Thomas B. Keefer OC4331/Summer 2005

3. LT Thomas B. Keefer OC4331/Summer 2005
Front (in General): Region where the rate of change of a certain physical property is an order of magnitude greater than the surrounding areas in the medium (the ocean in this case). (For this discussion, we will look primarily at temperature, salinity and density)
LT Thomas B. Keefer OC4331/Summer 2005

4. LT Thomas B. Keefer OC4331/Summer 2005
Front Properties:
Quasi Permanent
Resist destruction by turbulence
Need a frontogenesis mechanism
Strong gradient
Temperature, density and Salinity
Convergent Flow
Cause intense advection of 'different' water into a region
Flow can be across isohalines or isotherms
LT Thomas B. Keefer OC4331/Summer 2005

5. Oceanic front Classification
Density Front
Strong density gradient in frontal zone
Front causes water movement-flow follows isopycnals
Oceanic density fronts are analogous to atmospheric fronts
Shelf break fronts are of this type
Density-Compensating Front
Small or non-existent density gradient at the front
Interleaving and Intrusion present
Two properties of the front compensate in terms of density across the front
Shelf break fronts are of this type As Well
LT Thomas B. Keefer OC4331/Summer 2005

6. Density vs. Density Compensating
Dens. Comp.
LT Thomas B. Keefer OC4331/Summer 2005

7. LT Thomas B. Keefer OC4331/Summer 2005
Density fronts
Can be prograde or retrograde
Shelf water is less dense than slope water
Shelf water is more dense than slope water
LT Thomas B. Keefer OC4331/Summer 2005

8. LT Thomas B. Keefer OC4331/Summer 2005
Front Types:
Planetary
Only open ocean front
Separation of two water masses of different temperatures
Dramatic influence on air/sea mechanisms (heat budget)
Upwelling
Regions of long steady winds
Strong upwelling present
Shallow Sea
Separation of well mixed and stratified waters
Caused by competing forces of solar radiation (stratifies) and tidal outflow/inflow (mixing)
LT Thomas B. Keefer OC4331/Summer 2005

9. LT Thomas B. Keefer OC4331/Summer 2005
Front Types:
Plume
Estuarine- fan of fresh water into the salty ocean
Separation of two water masses of different Salinities
Strong turbulence in area of fresh/salty mixing
Estuarine
Similar to plume- separation of fresh and salty water
Vertical stratification caused by buoyancy (not outflow)
Shelf Break
Focus of this brief
Not very well understood (not very common)
Caused by the flow characteristics at the shelf break
LT Thomas B. Keefer OC4331/Summer 2005

10. LT Thomas B. Keefer OC4331/Summer 2005
Shelf Break Fronts:
Separation of warm, saline slope water from cool, fresh shelf water
Can be density or Density Compensating
Restricted to the very edge of the shelf and are stationary in the cross-shelf
Present most of the time and will re-form quickly after short disturbance
Drastically affect transfer of heat, salt and momentum from the shelf to slope region
LT Thomas B. Keefer OC4331/Summer 2005

11. Shelf Break Fronts: Is it really that hard?
Not present Everywhere
Mid Atlantic Bight, E. Bering Sea, Celtic Sea
Data collection can be difficult (shelf break)
All coastal (shallow) front mechanics are difficult
non-linear nature of the near shore
LT Thomas B. Keefer OC4331/Summer 2005

12. Shelf Break Fronts: Is it really that important?
Critical for understanding the budget between shelf and slope
Heat
Salt
Momentum
Eco-Systems
Fronts stop cross shelf transport of particulate matter
Extremely rich biologically
Commercial interest to fisheries
LT Thomas B. Keefer OC4331/Summer 2005

13. Shelf Break Fronts: How do they form?
Initial Conditions
Linear stratification at shelf break
No horizontal density gradients
Along shelf flow into frontogenesis region
This is the 'forcing'
Seaward (cross shelf) flow of bottom water
Caused by to ekman Flux
Transports light water under heavy
Overturning causes well mixed density field in the shelf break area
LT Thomas B. Keefer OC4331/Summer 2005

14. Shelf Break Fronts: How do they form?
In a phrase: 'Positive feedback Mechanism'
Current Conditions
Cross shelf flow still exists
Well mixed frontal zone at the break
Still stratified on both sides of the front development area
Now there is a large horizontal density gradient seaward of the shelf (well mixed shelf and stratified slop water mixing at the break)
Off-shore flow along the bottom still exists!!
LT Thomas B. Keefer OC4331/Summer 2005

15. Shelf Break Fronts: How do they form?
Off shore transport across break goes on
Confined to bottom layer
Particles ascend isopycnals as they move offshore
Need a replacement mechanism for this water that is moving up
Water is downwelled over the shelf to replace the upwelled water over the slope
This is a self perpetuating situation that remains in place and continues (pos. Feedback)
Now we have a shelf break front
LT Thomas B. Keefer OC4331/Summer 2005

16. Shelf Break Fronts: Lets make a model!
Early models don’t work well
Problems developing required along shelf velocity sheer (forcing) using only geostrophy (Ou 1983; Hseuh and Cushman- Roisin 1983)
Friction layer can be hard to model accurately but this is key
Frontogenesis mechanism understanding weak to non-existent/ initial thoughts probably misguided.
LT Thomas B. Keefer OC4331/Summer 2005

17. Shelf Break Fronts: Lets make a model!
New Model Goal: ".. To understand the three-dimensional circulation that results after allowing a highly idealized inflow to adjust dynamically, under the influence of bottom friction, vertical mixing and stratification"
Note: this model was not designed to actually be a shelf break front model solely but rather models the shelf break area. when the dynamics are modeled and run, the front development naturally takes place.
LT Thomas B. Keefer OC4331/Summer 2005

18. Shelf Break Fronts: Lets make a model!
Start with Primitive Equations for linear momentum
INSERT EQNS HERE
Define Variables
Ignore momentum advection based on Rd
Describe continuity equation in 3-d
Rigid lid surface condition
Hydrostatic pressure field
Free slip condition at coastal boundary
Set up physical domain of the modeled area
START THE PARTY!!
LT Thomas B. Keefer OC4331/Summer 2005

19. Shelf Break Fronts: Lets make a model!
LT Thomas B. Keefer OC4331/Summer 2005

20. Shelf Break Fronts: Run the Model!
Cross Shelf Velocity Profiles- Note Bottom
X-50Km
X-150Km
LT Thomas B. Keefer OC4331/Summer 2005

21. Shelf Break Fronts: Run the model!
Off shore flow
On shore flow
Shelf Break Area
Convergence Zone
X-150m
LT Thomas B. Keefer OC4331/Summer 2005

22. Shelf Break Fronts: Run the model!
The cross section of the shelf/slope interface shows the development of the horizontal density stratification. From left to right the cross shelf stations are at 50km, 100km and 150km. This is the primary driving force in building and maintaining these fronts.
LT Thomas B. Keefer OC4331/Summer 2005

23. Shelf Break Fronts: Run the model!
the horizontal density stratification is evident here. This density gradient is the reason that the particles ride upward on the seaward side of the shelf. The compensation for this on the shelf side is the primary development mechanism.
LT Thomas B. Keefer OC4331/Summer 2005

24. Shelf Break Fronts: Vary the input Parameters
model run profiled was for a 'standard' case but other cases were developed by Gawarkiewicz and Chapman during their modeling phase.
Details are beyond the scope of this brief
Some conclusions are important
Existence of the initial cross shore flow is needed; magnitude less important
Changes in initial stratification change width of front but not drastically
Front structure most dependant on bottom topography
LT Thomas B. Keefer OC4331/Summer 2005

25. Shelf Break Fronts: Does the Model Work?
The model is based on a few simplifications that may or may not be valid.
Neglect wind and eddy forcing
Neglect buoyancy flux induced by local fresh water run off areas
Constant eddy flux and diffusivity
Steady, idealized upstream boundary conditions
These simplifications, due to the refusal to handle a seasonal pycnocline, most accurately represent a winter regime.
LT Thomas B. Keefer OC4331/Summer 2005

26. Shelf Break Fronts: Does the Model Work?
Nantucket Shoals Experiment ( )
Existing data from this experiment (conducted by Beardsley, Chapman, Brink, Ramp and Schlitz) was used for model verification
LT Thomas B. Keefer OC4331/Summer 2005

27. Shelf Break Fronts: Does the Model Work?
Cross sections from Nantucket Shoals experiment.
Left summer; right winter
Summer has more prevalent front but front still exists in winter as a horizontal density gradient
Relative strength reasoned to be a function of initial degree of vertical stratification (seasonal Pycnocline caused by surface heating of shallower shelf water)
LT Thomas B. Keefer OC4331/Summer 2005

28. Shelf Break Fronts: Conclusions
Shallow water dynamics are difficult to model but very important to understand from ecological, scientific and commercial standpoints
Shelf break fronts play a key role in the composition of the near shelf environment in several parts of the world
Provided there is some along slope flow and favorable topography, shelf break fronts will form through a positive feedback mechanism between the slope and shelf waters
Shelf break fronts are present in both winter and summer seasons but grow stronger in summer due to the greater stratification of the shelf water
The model designed by Gawarkiewicz and chapman, 1992 handles a highly idealized (near winter) case very well
LT Thomas B. Keefer OC4331/Summer 2005

29. Shelf Break Fronts: References:
Journal of Physical Oceanography volume 15 pp "The role of Stratification in the Formation and Maintenance of Shelf Break Fronts"
Glen Gawarkiewicz and David C. Chapman
Woods Hole Oceanographic Institution
Journal of Physical Oceanography Volume 22 pp "The Nantucket Shoals Flux Experiment (NSFE79)"
Robert C. Beardsley, David C. Chapman and Kenneth H. Brink
Course Text:
LT Thomas B. Keefer OC4331/Summer 2005

30. Shelf Break Fronts: QUESTIONS?
LT Thomas B. Keefer OC4331/Summer 2005