Vorticity equation: Difference between revisions
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{{Short description|Equation describing the evolution of the vorticity of a fluid particle as it flows}} |
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{{Continuum mechanics|cTopic=Fluid mechanics}} |
{{Continuum mechanics|cTopic=Fluid mechanics}} |
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The '''vorticity equation''' of [[fluid dynamics]] describes evolution of the [[vorticity]] {{math|'''ω'''}} of a particle of a [[fluid dynamics|fluid]] as it moves with its [[flow (fluid)|flow]] |
The '''vorticity equation''' of [[fluid dynamics]] describes the evolution of the [[vorticity]] {{math|'''ω'''}} of a particle of a [[fluid dynamics|fluid]] as it moves with its [[flow (fluid)|flow]]; that is, the local rotation of the fluid (in terms of [[vector calculus]] this is the [[curl (mathematics)|curl]] of the [[flow velocity]]). The governing equation is:{{Equation box 1|cellpadding|border|indent=:|equation=<math> \begin{align} |
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The equation is: |
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:<math>\begin{align} |
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\frac{D\boldsymbol\omega}{Dt} &= \frac{\partial \boldsymbol \omega}{\partial t} + (\mathbf u \cdot \nabla) \boldsymbol \omega \\ |
\frac{D\boldsymbol\omega}{Dt} &= \frac{\partial \boldsymbol \omega}{\partial t} + (\mathbf u \cdot \nabla) \boldsymbol \omega \\ |
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&= (\boldsymbol \omega \cdot \nabla) \mathbf u - \boldsymbol \omega (\nabla \cdot \mathbf u) + \frac{1}{\rho^2}\nabla \rho \times \nabla p + \nabla \times \left( \frac{\nabla \cdot \tau}{\rho} \right) + \nabla \times \left( \frac{\mathbf B}{\rho} \right) \end{align}</math> |
&= (\boldsymbol \omega \cdot \nabla) \mathbf u - \boldsymbol \omega (\nabla \cdot \mathbf u) + \frac{1}{\rho^2}\nabla \rho \times \nabla p + \nabla \times \left( \frac{\nabla \cdot \tau}{\rho} \right) + \nabla \times \left( \frac{\mathbf B}{\rho} \right) \end{align} </math>|border colour=#0073CF|background colour=#F5FFFA}}where {{math|{{sfrac|''D''|''Dt''}}}} is the [[material derivative]] operator, {{math|'''u'''}} is the [[flow velocity]], {{mvar|ρ}} is the local fluid [[density]], {{mvar|p}} is the local [[pressure]], {{mvar|τ}} is the [[viscous stress tensor]] and {{math|'''B'''}} represents the sum of the external [[body force]]s. The first source term on the right hand side represents [[vortex stretching]]. |
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where {{math|{{sfrac|''D''|''Dt''}}}} is the [[material derivative]] operator, {{math|'''u'''}} is the [[flow velocity]], {{mvar|ρ}} is the local fluid [[density]], {{mvar|p}} is the local [[pressure]], {{mvar|τ}} is the [[viscous stress tensor]] and {{math|'''B'''}} represents the sum of the external [[body force]]s. The first source term on the right hand side represents [[vortex stretching]]. |
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The equation is valid in the absence of any concentrated [[torque]]s and line forces, for a compressible [[Newtonian fluid]]. |
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In the case of [[ |
The equation is valid in the absence of any concentrated [[torque]]s and line forces for a [[Compressibility|compressible]], [[Newtonian fluid]]. In the case of [[incompressible flow]] (i.e., low [[Mach number]]) and [[isotropic]] fluids, with [[conservative force|conservative]] body forces, the equation simplifies to the '''vorticity transport equation''': |
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:<math>\frac{D\boldsymbol\omega}{Dt} = \left(\boldsymbol{\omega} \cdot \nabla\right) \mathbf{u} + \nu \nabla^2 \boldsymbol{\omega}</math> |
:<math>\frac{D\boldsymbol\omega}{Dt} = \left(\boldsymbol{\omega} \cdot \nabla\right) \mathbf{u} + \nu \nabla^2 \boldsymbol{\omega}</math> |
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where {{mvar|ν}} is the [[viscosity|kinematic viscosity]] and |
where {{mvar|ν}} is the [[viscosity|kinematic viscosity]] and <math>\nabla^{2}</math> is the [[Laplace operator]]. Under the further assumption of two-dimensional flow, the equation simplifies to: |
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:<math>\frac{D\boldsymbol\omega}{Dt} = \nu \nabla^2 \boldsymbol{\omega}</math> |
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==Physical interpretation== |
==Physical interpretation== |
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* The term {{math|{{sfrac|''D'''''ω'''|''Dt''}}}} on the left-hand side is the [[substantive derivative|material derivative]] of the vorticity vector {{math|'''ω'''}}. It describes the rate of change of vorticity of the moving fluid particle. This change can be attributed to [[steady state flow|unsteadiness]] in the flow ({{math|{{sfrac|∂'''ω'''|∂''t''}}}}, the ''unsteady term'') or due to the motion of the fluid particle as it moves from one point to another ({{math|('''u''' ∙ ∇)'''ω'''}}, the ''[[convection]] term''). |
* The term {{math|{{sfrac|''D'''''ω'''|''Dt''}}}} on the left-hand side is the [[substantive derivative|material derivative]] of the vorticity vector {{math|'''ω'''}}. It describes the rate of change of vorticity of the moving fluid particle. This change can be attributed to [[steady state flow|unsteadiness]] in the flow ({{math|{{sfrac|∂'''ω'''|∂''t''}}}}, the ''unsteady term'') or due to the motion of the fluid particle as it moves from one point to another ({{math|('''u''' ∙ ∇)'''ω'''}}, the ''[[convection]] term''). |
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* The term {{math|('''ω''' ∙ ∇) '''u'''}} on the right-hand side describes the stretching or tilting of vorticity due to the flow velocity gradients. Note that {{math|('''ω''' ∙ ∇) '''u'''}} is a vector quantity, as {{math|'''ω''' ∙ ∇}} is a scalar differential operator, while {{math|∇'''u'''}} is a nine-element tensor quantity. |
* The term {{math|('''ω''' ∙ ∇) '''u'''}} on the right-hand side describes the stretching or tilting of vorticity due to the flow velocity gradients. Note that {{math|('''ω''' ∙ ∇) '''u'''}} is a vector quantity, as {{math|'''ω''' ∙ ∇}} is a scalar differential operator, while {{math|∇'''u'''}} is a nine-element tensor quantity. |
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* The term {{math|'''ω'''(∇ ∙ '''u''')}} describes [[vortex stretching|stretching of vorticity]] due to flow compressibility. It follows from the Navier-Stokes equation for [[continuity equation|continuity]], namely |
* The term {{math|'''ω'''(∇ ∙ '''u''')}} describes [[vortex stretching|stretching of vorticity]] due to flow compressibility. It follows from the Navier-Stokes equation for [[continuity equation|continuity]], namely <math display="block">\begin{align} |
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*:<math>\begin{align} |
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\frac{\partial\rho}{\partial t} + \nabla \cdot\left(\rho \mathbf u\right) &= 0 \\ |
\frac{\partial\rho}{\partial t} + \nabla \cdot\left(\rho \mathbf u\right) &= 0 \\ |
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\Longleftrightarrow \nabla \cdot \mathbf{u} &= -\frac{1}{\rho}\frac{d\rho}{dt} = \frac{1}{v}\frac{dv}{dt} |
\Longleftrightarrow \nabla \cdot \mathbf{u} &= -\frac{1}{\rho}\frac{d\rho}{dt} = \frac{1}{v}\frac{dv}{dt} |
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⚫ | |||
\end{align}</math> |
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⚫ | |||
* The term {{math|{{sfrac|1|''ρ''<sup>2</sup>}}∇''ρ'' × ∇''p''}} is the [[baroclinity|baroclinic term]]. It accounts for the changes in the vorticity due to the intersection of density and pressure surfaces. |
* The term {{math|{{sfrac|1|''ρ''<sup>2</sup>}}∇''ρ'' × ∇''p''}} is the [[baroclinity|baroclinic term]]. It accounts for the changes in the vorticity due to the intersection of density and pressure surfaces. |
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* The term {{math|∇ × ({{sfrac|∇ ∙ ''τ''|''ρ''}})}}, accounts for the diffusion of vorticity due to the viscous effects. |
* The term {{math|∇ × ({{sfrac|∇ ∙ ''τ''|''ρ''}})}}, accounts for the diffusion of vorticity due to the viscous effects. |
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=== Simplifications === |
=== Simplifications === |
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* In case of [[conservative force|conservative body forces]], {{math|∇ × '''B''' |
* In case of [[conservative force|conservative body forces]], {{math|1=∇ × '''B''' = 0}}. |
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* For a [[barotropic|barotropic fluid]], {{math|∇''ρ'' × ∇''p'' |
* For a [[barotropic|barotropic fluid]], {{math|1=∇''ρ'' × ∇''p'' = 0}}. This is also true for a constant density fluid (including incompressible fluid) where {{math|1=∇''ρ'' = 0}}. Note that this is not the same as an [[incompressible flow]], for which the barotropic term cannot be neglected. |
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* For [[inviscid]] fluids, the viscosity tensor {{mvar|τ}} is zero. |
* For [[inviscid]] fluids, the viscosity tensor {{mvar|τ}} is zero. |
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Thus for an inviscid, barotropic fluid with conservative body forces, the vorticity equation simplifies to |
Thus for an inviscid, barotropic fluid with conservative body forces, the vorticity equation simplifies to |
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: <math>\frac{ |
: <math>\frac{D}{Dt} \left( \frac{\boldsymbol \omega}{\rho} \right) = \left( \frac{\boldsymbol\omega}{\rho} \right) \cdot \nabla \mathbf u </math> |
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Alternately, in case of incompressible, inviscid fluid with conservative body forces, |
Alternately, in case of incompressible, inviscid fluid with conservative body forces, |
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: <math>\frac{ |
: <math>\frac{D \boldsymbol \omega}{Dt} = \frac{\partial \boldsymbol \omega}{\partial t} + (\mathbf u \cdot \nabla)\boldsymbol \omega = (\boldsymbol \omega \cdot \nabla) \mathbf u </math><ref>{{cite book |last1=Fetter |first1=Alexander L. |last2=Walecka |first2=John D. |title=Theoretical Mechanics of Particles and Continua |date=2003 |publisher=Dover Publications |isbn=978-0-486-43261-8 |page=351 |edition=1st}}</ref> |
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For a brief review of additional cases and simplifications, see also.<ref>{{cite web|first=K. P.|last=Burr |title=Marine Hydrodynamics, Lecture 9|website=MIT Lectures|url= |
For a brief review of additional cases and simplifications, see also.<ref>{{cite web| first=K. P.| last=Burr |title=Marine Hydrodynamics, Lecture 9| website=MIT Lectures| url=https://ocw.mit.edu/courses/mechanical-engineering/2-20-marine-hydrodynamics-13-021-spring-2005/lecture-notes/lecture9.pdf}}</ref> For the vorticity equation in turbulence theory, in context of the flows in oceans and atmosphere, refer to.<ref>{{cite web | first=Richard L. | last=Salmon | title=Lectures on Geophysical Fluid Dynamics, Chapter 4 | website=Oxford University Press; 1 edition (February 26, 1998) | url=http://pordlabs.ucsd.edu/rsalmon/chap4.pdf}}</ref> |
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==Derivation== |
==Derivation== |
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The vorticity equation can be derived from the [[Navier–Stokes equations|Navier–Stokes]] equation for the conservation of [[angular momentum]]. In the absence of any concentrated [[torque]]s and line forces, one obtains |
The vorticity equation can be derived from the [[Navier–Stokes equations|Navier–Stokes]] equation for the conservation of [[angular momentum]]. In the absence of any concentrated [[torque]]s and line forces, one obtains: |
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:<math>\frac{D \mathbf{u}}{D t} = \frac{\partial \mathbf{u}}{\partial t} + \left(\mathbf{u} \cdot \nabla\right) \mathbf{u} = -\frac{1}{\rho} \nabla p |
:<math>\frac{D \mathbf{u}}{D t} = \frac{\partial \mathbf{u}}{\partial t} + \left(\mathbf{u} \cdot \nabla\right) \mathbf{u} = -\frac{1}{\rho} \nabla p + \frac{\nabla \cdot \tau}{\rho} + \frac{\mathbf{B}}{\rho}</math> |
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Now, vorticity is defined as the curl of the flow velocity vector |
Now, vorticity is defined as the curl of the flow velocity vector; taking the [[Curl_(mathematics)|curl]] of momentum equation yields the desired equation. The following identities are useful in derivation of the equation: |
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The following identities are useful in derivation of the equation: |
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:<math>\begin{align} |
:<math>\begin{align} |
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\boldsymbol{\omega} &= \nabla \times \mathbf{u} \\ |
\boldsymbol{\omega} &= \nabla \times \mathbf{u} \\ |
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\end{align}</math> |
\end{align}</math> |
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where |
where <math>\phi</math> is any scalar field. |
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==Tensor notation== |
==Tensor notation== |
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==References== |
==References== |
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{{reflist}} |
{{reflist}} |
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⚫ | *{{cite journal | first1= Utpal |last1=Manna |first2=S. S. |last2=Sritharan | title= Lyapunov Functionals and Local Dissipativity for the Vorticity Equation in {{mvar|L{{isup|p}}}} and Besov spaces | journal = Differential and Integral Equations | volume= 20 |number =5 |year= 2007|pages= 581–598}} |
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== Further reading == |
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⚫ | *{{cite journal | first1= Utpal |last1=Manna |first2=S. S. |last2=Sritharan | title= Lyapunov Functionals and Local Dissipativity for the Vorticity Equation in {{mvar|L{{isup|p}}}} and Besov spaces | journal = Differential and Integral Equations | volume= 20 |number =5 |year= 2007|pages= 581–598|doi=10.57262/die/1356039440 |s2cid=50701138 |arxiv=0802.2898 }} |
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* {{cite book|first1=V. |last1=Barbu |first2=S. S. |last2=Sritharan |chapter={{mvar|M}}-Accretive Quantization of the Vorticity Equation |title=Semi-Groups of Operators: Theory and Applications |editor-first=A. V. |editor-last=Balakrishnan |publisher=Birkhauser |location=Boston |date=2000 |pages=296–303 |chapter-url=http://www.nps.edu/Academics/Schools/GSEAS/SRI/BookCH12.pdf}} |
* {{cite book|first1=V. |last1=Barbu |first2=S. S. |last2=Sritharan |chapter={{mvar|M}}-Accretive Quantization of the Vorticity Equation |title=Semi-Groups of Operators: Theory and Applications |editor-first=A. V. |editor-last=Balakrishnan |publisher=Birkhauser |location=Boston |date=2000 |pages=296–303 |chapter-url=http://www.nps.edu/Academics/Schools/GSEAS/SRI/BookCH12.pdf}} |
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* {{cite journal|first=A. M. |last=Krigel |title=Vortex evolution |journal=Geophysical & Astrophysical Fluid Dynamics |date=1983 |volume=24 |pages=213–223}} |
* {{cite journal|first=A. M. |last=Krigel |title=Vortex evolution |journal=Geophysical & Astrophysical Fluid Dynamics |date=1983 |volume=24 |issue=3 |pages=213–223|doi=10.1080/03091928308209066 |bibcode=1983GApFD..24..213K }} |
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{{More citations needed|date=May 2009}} |
{{More citations needed|date=May 2009}} |
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[[Category:Equations of fluid dynamics]] |
[[Category:Equations of fluid dynamics]] |
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[[Category:Transport phenomena]] |
Latest revision as of 12:05, 15 August 2024
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Continuum mechanics |
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The vorticity equation of fluid dynamics describes the evolution of the vorticity ω of a particle of a fluid as it moves with its flow; that is, the local rotation of the fluid (in terms of vector calculus this is the curl of the flow velocity). The governing equation is:
where D/Dt is the material derivative operator, u is the flow velocity, ρ is the local fluid density, p is the local pressure, τ is the viscous stress tensor and B represents the sum of the external body forces. The first source term on the right hand side represents vortex stretching.
The equation is valid in the absence of any concentrated torques and line forces for a compressible, Newtonian fluid. In the case of incompressible flow (i.e., low Mach number) and isotropic fluids, with conservative body forces, the equation simplifies to the vorticity transport equation:
where ν is the kinematic viscosity and is the Laplace operator. Under the further assumption of two-dimensional flow, the equation simplifies to:
Physical interpretation
[edit]- The term Dω/Dt on the left-hand side is the material derivative of the vorticity vector ω. It describes the rate of change of vorticity of the moving fluid particle. This change can be attributed to unsteadiness in the flow (∂ω/∂t, the unsteady term) or due to the motion of the fluid particle as it moves from one point to another ((u ∙ ∇)ω, the convection term).
- The term (ω ∙ ∇) u on the right-hand side describes the stretching or tilting of vorticity due to the flow velocity gradients. Note that (ω ∙ ∇) u is a vector quantity, as ω ∙ ∇ is a scalar differential operator, while ∇u is a nine-element tensor quantity.
- The term ω(∇ ∙ u) describes stretching of vorticity due to flow compressibility. It follows from the Navier-Stokes equation for continuity, namely where v = 1/ρ is the specific volume of the fluid element. One can think of ∇ ∙ u as a measure of flow compressibility. Sometimes the negative sign is included in the term.
- The term 1/ρ2∇ρ × ∇p is the baroclinic term. It accounts for the changes in the vorticity due to the intersection of density and pressure surfaces.
- The term ∇ × (∇ ∙ τ/ρ), accounts for the diffusion of vorticity due to the viscous effects.
- The term ∇ × B provides for changes due to external body forces. These are forces that are spread over a three-dimensional region of the fluid, such as gravity or electromagnetic forces. (As opposed to forces that act only over a surface (like drag on a wall) or a line (like surface tension around a meniscus).
Simplifications
[edit]- In case of conservative body forces, ∇ × B = 0.
- For a barotropic fluid, ∇ρ × ∇p = 0. This is also true for a constant density fluid (including incompressible fluid) where ∇ρ = 0. Note that this is not the same as an incompressible flow, for which the barotropic term cannot be neglected.
- For inviscid fluids, the viscosity tensor τ is zero.
Thus for an inviscid, barotropic fluid with conservative body forces, the vorticity equation simplifies to
Alternately, in case of incompressible, inviscid fluid with conservative body forces,
For a brief review of additional cases and simplifications, see also.[2] For the vorticity equation in turbulence theory, in context of the flows in oceans and atmosphere, refer to.[3]
Derivation
[edit]The vorticity equation can be derived from the Navier–Stokes equation for the conservation of angular momentum. In the absence of any concentrated torques and line forces, one obtains:
Now, vorticity is defined as the curl of the flow velocity vector; taking the curl of momentum equation yields the desired equation. The following identities are useful in derivation of the equation:
where is any scalar field.
Tensor notation
[edit]The vorticity equation can be expressed in tensor notation using Einstein's summation convention and the Levi-Civita symbol eijk:
In specific sciences
[edit]Atmospheric sciences
[edit]In the atmospheric sciences, the vorticity equation can be stated in terms of the absolute vorticity of air with respect to an inertial frame, or of the vorticity with respect to the rotation of the Earth. The absolute version is
Here, η is the polar (z) component of the vorticity, ρ is the atmospheric density, u, v, and w are the components of wind velocity, and ∇h is the 2-dimensional (i.e. horizontal-component-only) del.
See also
[edit]References
[edit]- ^ Fetter, Alexander L.; Walecka, John D. (2003). Theoretical Mechanics of Particles and Continua (1st ed.). Dover Publications. p. 351. ISBN 978-0-486-43261-8.
- ^ Burr, K. P. "Marine Hydrodynamics, Lecture 9" (PDF). MIT Lectures.
- ^ Salmon, Richard L. "Lectures on Geophysical Fluid Dynamics, Chapter 4" (PDF). Oxford University Press; 1 edition (February 26, 1998).
Further reading
[edit]- Manna, Utpal; Sritharan, S. S. (2007). "Lyapunov Functionals and Local Dissipativity for the Vorticity Equation in Lp and Besov spaces". Differential and Integral Equations. 20 (5): 581–598. arXiv:0802.2898. doi:10.57262/die/1356039440. S2CID 50701138.
- Barbu, V.; Sritharan, S. S. (2000). "M-Accretive Quantization of the Vorticity Equation" (PDF). In Balakrishnan, A. V. (ed.). Semi-Groups of Operators: Theory and Applications. Boston: Birkhauser. pp. 296–303.
- Krigel, A. M. (1983). "Vortex evolution". Geophysical & Astrophysical Fluid Dynamics. 24 (3): 213–223. Bibcode:1983GApFD..24..213K. doi:10.1080/03091928308209066.
This article needs additional citations for verification. (May 2009) |