Stommel Model: Munk Model.

Slides:

Advertisements

Similar presentations

SIO 210: Dynamics VI (Potential vorticity) L. Talley Fall, 2014 Talley SIO210 (2014)1 Variation of Coriolis with latitude: “β” Vorticity Potential vorticity.

Advertisements

Boundary Layer Flow Describes the transport phenomena near the surface for the case of fluid flowing past a solid object.

What drives the oceanic circulation ? Thermohaline driven Wind driven.

Western Intensification Subtropical gyres are asymmetric & have intense WBC’s Western intensification is created by the conservation of angular momentum.

Ocean & Atmospheric circulation redux 1) Unequal planetary heating creates pressure gradients which make winds blow on ocean surface in trade-wind & westerly.

What drives the oceanic circulation ? Thermohaline driven (-> exercise) Wind driven (-> Sverdrup, Ekman)

The Subtropical Gyres: setting the stage for generating a more realistic gyre Ekman used an ideal, infinite ocean, no slopes in sea level, or variations.

CHE/ME 109 Heat Transfer in Electronics

SIO 210: Dynamics VI (Potential vorticity) L. Talley Fall, 2014 (Section 2: including some derivations) Talley SIO210 (2014)1 Variation of Coriolis with.

Wind-driven Ocean Circulation

The General Circulation of the Atmosphere Background and Theory.

Atmospheric Science 4320 / 7320 Lab Portion / Anthony R. Lupo.

The Equations of Motion

LAMINAR PLANE COUETTE AND OPEN CHANNEL FLOW

Hans Burchard Leibniz Institute for Baltic Sea Research Warnemünde Coastal Ocean Dynamics First course: Hydrodynamics.

Wind-driven circulation II

Wind Driven Circulation I: Planetary boundary Layer near the sea surface.

TropicalM. D. Eastin Cylindrical Coordinate System.

Evaporative heat flux (Q e ) 51% of the heat input into the ocean is used for evaporation. Evaporation starts when the air over the ocean is unsaturated.

Vorticity Measure of angular momentum for a fluid

Alternative derivation of Sverdrup Relation Construct vorticity equation from geostrophic balance (1) (2)  Integrating over the whole ocean depth, we.

Rossby Wave Two-layer model with rigid lid η=0, p s ≠0 The pressures for the upper and lower layers are The perturbations are 

Term Paper Guide Find an oceanic or relevant atmospheric phenomenon you are interested in (e.g., ENSO, PDO, AMO, TAV, IOD, NAO, hurricane activity, regional.

Mass Transfer Coefficient

For a rotating solid object, the vorticity is two times of its angular velocity Vorticity In physical oceanography, we deal mostly with the vertical component.

Wind Driven Circulation III Closed Gyre Circulation Quasi-Geostrophic Vorticity Equation Westward intensification Stommel Model Munk Model Inertia boundary.

For a rotating solid object, the vorticity is two times of its angular velocity Vorticity In physical oceanography, we deal mostly with the vertical component.

OCN 5401 Chapter 6 Effect of Earth’s Rotation Instructor: Dr. George A. Maul / X 7453.

Gulf stream, recirculation, and other western boundary layer currents

EVAT 554 OCEAN-ATMOSPHERE DYNAMICS SVERDRUP TRANSPORT LECTURE 15 (Reference: Peixoto & Oort, Chapter 8,10)

Schedule for final exam

EVAT 554 OCEAN-ATMOSPHERE DYNAMICS TIME-DEPENDENT DYNAMICS; WAVE DISTURBANCES LECTURE 21.

For most of the basin Question

EVAT 554 OCEAN-ATMOSPHERE DYNAMICS GYRE-SCALE OCEAN CIRCULATION LECTURE 16 (Reference: Peixoto & Oort, Chapter 8,10)

Question: Why 45 o, physics or math? andare perpendicular to each other 45 o relation holds for boundary layer solution Physics: Coriolis force is balanced.

12.808, Problem 1, problem set #2 This is a 3 part question dealing with the wind-driven circulation. At 26 o N in the N. Atlantic, the average wind stress.

Wind-forced solutions:

Ocean Dynamics Previous Lectures So far we have discussed the equations of motion ignoring the role of friction In order to understand ocean circulations.

Wind-driven circulation II ●Wind pattern and oceanic gyres ●Sverdrup Relation ●Vorticity Equation.

CoriolisPressure Gradient x z CURRENTS WITH FRICTION Nansen’s qualitative argument on effects of friction CoriolisPressure Gradient x y CoriolisPressure.

Stommel and Munk Theories of the Gulf Stream October 8.

The Oceanic General Circulation. Regardless of hemisphere or ocean basin, there is an intense current on the western boundary.

1. The geostrophic wind: scale analysis 2. Effects of friction 3. The gradient wind ATOC 4720 class33.

GFD 2007 Boundary Layers The idea of the boundary layer dates back at least to the time of Prandtl (1904, see the article: Ludwig Prandtl ’ s boundary.

Viscosità Equazioni di Navier Stokes. Viscous stresses are surface forces per unit area. (Similar to pressure) (Viscous stresses)

Sverdrup, Stommel, and Munk Theories of the Gulf Stream

CEE 262A H YDRODYNAMICS Lecture 17 Geostrophy. Often in analyzing large-scale flows we find that the momentum equations simplify greatly, i.e. we can.

Reynolds Number (Re) Viscosity: resistance of a liquid to change of form. Inertia: resistance of an object (body) to a change in its state of motion.

Class Meeting Nov. 26, 2:00pm-4:45pm

Define and we have • At the sea surface (z=0), the surface current flows at 45o to the right of the wind direction Depends on constant Az => • Current.

The Boussinesq and the Quasi-geostrophic approximations

Geostrophic adjustment

Wind-driven circulation

Define and we have • At the sea surface (z=0), the surface current flows at 45o to the right of the wind direction Depends on constant Az => • Current.

Define and we have • At the sea surface (z=0), the surface current flows at 45o to the right of the wind direction Depends on constant Az => • Current.

Chapter 4 Fluid Mechanics Frank White

Assume geostrophic balance on -plane approximation, i.e.,

Ekman layer at the bottom of the sea

GFD 2007 Boundary Layers: Homogeneous Ocean Circulation

Wind Driven Circulation III

Dynamics Vorticity In the previous lecture, we used “scaling” to simplify the equations of motion and found that, to first order, horizontal winds are.

Munk model Lateral friction becomes important in WBL.

Damped Inertial oscillations

The Bernoulli Equation

Some Idealized Thought Experiments of Wind-driven

Lecture 10: Dynamics: Sverdrup Interior and Western Boundary Currents Introductive Physical Oceanography This PowerPoint was prepared for purposes of.

Western Boundary Currents

Week 6-7: Wind-driven ocean circulation Tally’s book, chapter 7

TALLEY Copyright © 2011 Elsevier Inc. All rights reserved

Geostrophic adjustment

Presentation transcript:

Stommel Model: Munk Model

Munk model Lateral friction becomes important in WBL. Within the boundary layer, let , we have , Wind stress curl is the same as in the interior, becomes negligible in the boundary layer. For the lowest order, . If we let , we have . And for , . . The general solution is Since , C1=C2=0.

Using the no-slip boundary condition at x=0, Total solution Using the no-slip boundary condition at x=0,  .to , Western boundary current

Are nonlinear terms negligible? Given The cross-stream distance from boundary to maximum velocity is The ratio between the nonlinear and dominant viscous terms is where The continuity relation is also used: Using U=O(2 cm/s), ß=O(10-13 cm-1 s-1), AH=4106 cm2/s, we have R=4. i.e., the nonlinear terms neglected are larger than the retained viscous terms, which causes an internal inconsistency within the frictional boundary layer.

Inertial Boundary Layer If >>S and M, Given a boundary layer exists in the west where Re-scaling with , we have Conservation of potential vorticity. or

Inertial Currents with Small Friction In the presence of a small lateral friction, we can derive the perturbation equation as which makes the boundary layer possible only in the western ocean. Moreover, it can be shown that a inertial-vicious boundary layer can be generated in the northern part of the basin where characterized by a standing Rossby wave.

Assume the simple balance A parcel coming into the boundary layer has The effect of friction is reduced and the boundary layer is broadened.

Bryan (1963) integrates the vorticity equation with nonlinear term and lateral friction. The Reynolds number is define as And I/M ranges from 0.56 for Re=5 to 1.29 for Re=60. Number of undulation  Increases to compensate for countercurrent

(2x10-28) Veronis (1966), nonlinear Stommel Model Both the Sverdrup and western boundary layer solutions require: 0 (f changes with latitude) Relative vorticity  is small compared to f. When f, the circulation pattern becomes more symmetric with wind vorticity input balanced by frictional effect throughout the whole basin