- Vorticity equation
The vorticity equation is an important "prognostic equation" in the
atmospheric sciences . Vorticity is a vector, therefore, there are three components. The equation of vorticity (three components in the canonical form) describes the total derivative (that is, the local change due to local change with time andadvection ) ofvorticity , and thus can be stated in either "relative" or "absolute" form.The more compact version is that for "absolute vorticity", component , using the pressure system:
:
Here, is
density , "u", "v", and are the components of windvelocity , and is the 2-dimensional (i.e. horizontal-component-only)del .The terms on the RHS denote the positive or negative generation of "absolute vorticity" by
divergence of air, twisting of the axis of rotation, andbaroclinity , respectively.Fluid dynamics
The vorticity equation describes the evolution of the vorticity of a fluid element as it moves around. The vorticity equation can be derived from the conservation of momentum equation. [ Derivation of the vorticity equationIn the absence of any concentrated torques and line forces, the "momentum conservation equation" gives,
:
Now, vorticity is defined as the curl of the velocity vector . Taking curl of momentum equation yields the desired equation. The following identities are useful in derivation of the equation, :::, where is a scalar.:
] In its general vector form it may be expressed as follows,
:
where, is the velocity vector, is the density, is th pressure, is the viscous stress tensor and is the body force term.
Equivalently in tensor notation,
:
where, we have used the Einstein summation convention, and is the
Levi-Civita symbol .Physical Interpretation
* The term is the material derivative of the vorticity vector . It describes the rate of change of vorticity of a fluid particle (or in other words the angular acceleration of the fluid particle). This can change due to the unsteadiness in the flow captured by (the unsteady term) or due to the motion of the fluid particle as it moves from one point to another, (the convection term).
* The first term on the RHS of the vorticity equation, , describes the stretching or tilting of vorticity due to the velocity gradients. Note that this is a tensor with nine terms.
* The next term, , describes stretching of vorticity due to flow compressibility.The flow "continuity equation" states that,:This can be rewritten as, :
where is the specific volume of the fluid element. Thus one can think of as a measure of flow compressibility.] Sometimes the negative sign is included in the term.
* The third term, is the baroclinic term. It accounts for the changes in the vorticity due to the intersection of density and temperature surfaces.
* , accounts for the diffusion of vorticity due to the viscous effects.
* provides for changes due to body forces. [ A body force is one which is proportional to mass/volume/charge on a body. Such forces act over the whole volume of the body as opposed to a surface forces which act only on the surface. Examples of body forces are gravitational force, electromagnetic force, etc. Examples of surface forces are friction, pressure force, etc. Also there are line forces, like surface tension.]
Simplifications
# In case of conservative body forces, .
# For a barotropic fluid, . This is also true for a constant density fluid where . [Note that incompressible fluid (constant density fluid) is not same asincompressible flow and the barotropic term can not be neglected in case of incompressible flow. ]
# Forinviscid fluids, .Thus for an inviscid, barotropic fluid with conservative body forces, the vorticity equation simplifies to, [ We use the continuity equation to get to this form.] :
Alternately, in case of incompressible, inviscid fluid with conservative body forces, :
Notes
ee also
*
Vorticity
*Barotropic vorticity equation
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