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SCALING AND NON-DIMENSIONAL NUMBERS

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1 SCALING AND NON-DIMENSIONAL NUMBERS
Scaling with: For example: ratio of Inertia to Rotation

2 For example: ratio of Inertia to Rotation
For Ro << 1, e.g., Ro ~ 0.01, inertial accelerations are negligible and the motion is “linear” Example: U = 0.1 m/s, f = 10-4 s-1, L = 10 km

3 Ratio of Friction to Rotation
For Ev << 1, e.g., Ev ~ 0.01, frictional effects are negligible and the motion is dominated by Coriolis accelerations Example: Ax = 103 m2/s, f = 10-4 s-1, L = 10 km Example: Az = 10-3 m2/s, f = 10-4 s-1, H = 10 m

4 H L U 100 105 10-1 1 10 104 U/t U2/L fU AxU/L2 AzU/H2 10-5 10-7 ? 10-8
Scaling is very important to help us diagnose the relevant forces driving the flow in a given area (horizontal momentum). Local Inertial Coriolis Pres. Grad Hor. Fric. Ver. Fric. H L U 100 105 10-1 1 10 104 U/t U2/L fU AxU/L2 AzU/H2 10-5 10-7 ? 10-8 10-4 10-6 t = 12 h ~ 104 s ; Ax = 103 m2/s; Az = 10-2 m2/s For vertical momentum the concern is with the stability of the water column (density distribution with depth)

5 STABILITY < 0 [m-1]

6 Perturbations to the pycnocline (region of maximum stability) cause oscillations.
The frequency of the oscillations (radians / s) is given by: Buoyancy Frequency or Brunt-Väisälä Frequency A stable water column does not necessarily represent zero vertical exchange of properties

7 DOUBLE DIFFUSION S1, T1 S2, T2 S1 > S2 T1 > T2 Salt Fingers

8 Salt Fingers Experiment

9 Example of Salt Fingers (Kuroshio waters interacting with waters from Sea of Japan – through Tsugaru Strait) AIST Japan From Miyake et al. (1995, Journal of Oceanogr., 51, )

10 Requirements for Salt Fingers: a) dS/dz > 0 dT/dz > 0
b) Small density ratios c) Staircase in profiles From Miyake et al. (1995, Journal of Oceanogr., 51, )

11 From Miyake et al. (1995, Journal of Oceanogr., 51, 99-109)

12 From Miyake et al. (1995, Journal of Oceanogr., 51, 99-109)

13 S1, T1 S2, T2 S2 > S1 T2 > T1 Layering

14 heat flux from below Layering Experiment

15 Data from the Arctic From Kelley et al. (2002, The Diffusive Regime of Double-Diffusive Convection)

16 SHEARED FLOW AND STRATIFICATION
Click on image to see animation May cause instabilities like the one above (Kelvin-Helmholtz)

17 What will determine whether these waves become unstable?
Richardson Number

18 Ri < 0.25 necessary condition for instabilities to develop
Overall Richardson Number Ri < 0.25 necessary condition for instabilities to develop (0.30 from observations in natural environments)

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