TEST HEAD CASE: Difference between revisions

Revision as of 20:13, 15 April 2008

Sediment Test Headland Case

This test case checks the ability of a model to represent 1) simplified alongshore transport, 2) implementation of open boundary conditions, and 3) resuspension, transport, and deposition of suspended-sediment. This case is based on Signell and Geyer (1991).

Domain

The model domain is open at the east and west ends, has a straight wall at the north end, and a parabolic headland along the south wall.

Model Parameter	Variable	Value
Length (east-west)	l	100000 m
Width (north-south)	w	50000 m
Depth	h	20 m

Bottom Sediment

Single grain size on bottom:

Model Parameter	Variable	Value
Size	D₅₀	0.1 mm
Density	ρ_s	2650 kg/m³
Settling Velocity	w_s	0.50 mm/s
Critical shear stress	τ_c	0.05 N/m²
Bed thickness	bed_thick	0.005 m
Erosion Rate	E₀	5e-5 kg/m²/s

Forcing

Coriolis f = 1.0 e-4
No heating/cooling
No wind

Initial Conditions

u = 0 m³
Salinity = 0
Temperature = 20^oC

Bathymetry:
Depths increase linearly (slope = 0.0067) from a minimum depth of 2 m at all alongshore points from the southern land boundary offshore to a maximum depth of 20 m at a point 3 km offshore. Offshore of 3 km there is a constant depth of 20 m.

Boundary Conditions

North, south = walls with no fluxes, no friction
South wall = parabolic headland shape
Bottom roughness Z₀ = 0.015 m

Flow and elevation at western boundary is imposed.
Flow on eastern boundary is open radiation condition, or water level based, or Kelvin wave solution.

Flow and elevation, eastern/western boundaries:

Reference velocity u₀ = 0.5 m/s
Celerity C= √(g * 20.0)
Reference water level ζ₀ = u₀/√(g/20)
Wave period T = 12 hours (43200 seconds)
Wave length L = C * T
Wave number k = (2 * π)/L

For each point y along the boundary at time t:

Water level $\zeta \,=\,\zeta _{0}*exp(-f*y/C)*cos(k*(x-C*t))$
Note: x at western boundary is -L/2
Depth-mean flow $<u>\,=\,{\sqrt {g/20}}*\zeta (y)$

Sediment flux calculated by model
Surface = free surface, no fluxes

Output (ASCII files suitable for plotting)

After 10 days :
Bed thickness

Physical Constants

Gravitational acceleration $g\,=\,9.81\,m/s^{2}$
Von Karman's constant ? = 0.41
Dynamic viscosity (and minimum diffusivity) $\nu \,=\,1e-6\,m^{2}/s$

Note:

If a model incorporates physical constants that differ from these, and/or automatically calculates some values specified here, please specify the values used.

Results

**Figure 1.** Plan view of final bathymetric change.

Simulations were conducted for 3.0 days. Final bed thickness is shown in Figure 1.

@@ Line 89: / Line 89: @@
 Flow and elevation, eastern/western boundaries: <br>
-Reference velocity <math>u_{0} \,= \,0.5 \,m/s</math><br>
+Reference velocity <span class="blue">u<sub>0</sub></span> = 0.5 m/s<br>
-Celerity <math>C \,= \sqrt{g * 20.0}</math><br>
+Celerity <span class="blue">C</span>= <span>&radic;(g * 20.0)</span><br>
-Reference water level <math>\zeta_{0} \,= \,u_{0}/\sqrt{g/20}</math><br>
+Reference water level <span class="blue">&zeta;<sub>0</sub><span> = <span class="blue">u<sub>0</sub></span>/&radic;(g/20)<br>
 Wave period T = 12 hours (43200 seconds)<br>
 Wave length L = C * T <br>

TEST HEAD CASE: Difference between revisions

Revision as of 20:13, 15 April 2008

Contents

Domain

Bottom Sediment

Forcing

Initial Conditions

Boundary Conditions

Output (ASCII files suitable for plotting)

Physical Constants

Results

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