Cylindrical3D/Linearization

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Linearized Equations in Cylindrical Coordinates[edit]

Eulerian Formulation of Nonlinear Governing Equations[edit]

From our more detailed, accompanying discussion we pull the Eulerian representation of the set of principal governing equations written in cylindrical coordinates.


ϖ Component of Euler Equation

ϖ˙t+[ϖ˙ϖ˙ϖ]+[φ˙ϖ˙φ]+[z˙ϖ˙z]ϖφ˙2=1ρPϖΦϖ


φ Component of Euler Equation


(ϖφ˙)t+[ϖ˙(ϖφ˙)ϖ]+[φ˙(ϖφ˙)φ]+[z˙(ϖφ˙)z]+ϖ˙φ˙=1ϖ[1ρPφ+Φφ]


z Component of Euler Equation

z˙t+[ϖ˙z˙ϖ]+[φ˙z˙φ]+[z˙z˙z]=1ρPzΦz


Equation of Continuity

ρt+1ϖϖ[ρϖϖ˙]+1ϖφ[ρϖφ˙]+z[ρz˙]=0

These match, for example, equations (3.1) - (3.4) of Papaloizou & Pringle (1984, MNRAS, 208, 721-750), hereafter, PPI.

Linearization[edit]

If we assume that the initial equilibrium configuration is axisymmetric with no radial or vertical velocity, the linearized equations become:

Linearizing Radial Component of Euler Equation[edit]

ϖ˙'t+[φ˙0ϖ˙'φ]ϖ(φ˙0+φ˙')2

=

1(ρ0+ρ')(P0+P')ϖ(Φ0+Φ')ϖ

ϖ˙'t+[φ˙0ϖ˙'φ]ϖ(φ˙0)22ϖ(φ˙0φ˙')

=

1ρ0P'ϖ[1ρ0P0ϖ](1ρ'ρ0)(Φ0+Φ')ϖ

ϖ˙'t+φ˙0ϖ˙'φ2ϖ(φ˙0φ˙')+[1ρ0P'ϖρ'ρ02P0ϖ]+Φ'ϖ

=

{ϖ(φ˙0)21ρ0P0ϖΦ0ϖ}

ϖ˙'t+φ˙0ϖ˙'φ2ϖ(φ˙0φ˙')+[ϖ(P'ρ0)]+Φ'ϖ

=

0.

This last expression has been obtained by recognizing that, in the next-to-last expression: (1) The terms inside the curly braces on the right-hand side collectively provide a statement of equilibrium (in the radial-coordinate direction) in the initial, unperturbed configuration and therefore the terms sum to zero; and (2) the terms inside square brackets on the left-hand side can be rewritten in a more compact form because we have adopted a polytropic equation of state to build the unperturbed initial equilibrium configuration and are examining only adiabatic perturbations with γ=(n+1)/n, in which case,

P0P0=(n+1)nρ0ρ0,

      and      

P'P0=γρ'ρ0.


Linearizing Azimuthal Component of Euler Equation[edit]

Keeping in mind that the initial equilibrium configuration is axisymmetric — that is, equilibrium parameters exhibit no variation in the azimuthal direction — and, in addition, φ˙0 exhibits no variation in the vertical direction, we have,

(ϖφ˙')t+(ϖ˙')(ϖφ˙0)ϖ+(φ˙0)(ϖφ˙')φ+(ϖ˙')φ˙0

=

1ϖ[1ρ0P'φ+Φ'φ]

(ϖφ˙')t+(φ˙0)(ϖφ˙')φ+ϖ˙'ϖ[(ϖ2φ˙0)ϖ]

=

1ϖ[φ(P'ρ0)+Φ'φ].

Linearizing Vertical Component of Euler Equation[edit]

z˙'t+(φ˙0)z˙'φ

=

1(ρ0+ρ')(P0+P')z(Φ0+Φ')z

 

=

1ρ0P'z[1ρ0P0z](1ρ'ρ0)(Φ0+Φ')z

z˙'t+(φ˙0)z˙'φ+[1ρ0P'zρ'ρ02P0z]+Φ'z

=

{1ρ0P0zΦ0z}

z˙'t+(φ˙0)z˙'φ+[z(P'ρ0)]+Φ'z

=

0,

where the logic followed in deriving the last expression from the next-to-last one is directly analogous to the logic used, above, in obtaining the final expression for the radial component of the linearized Euler equation.

Linearizing Continuity Equation[edit]

ρ't

=

1ϖϖ[ρ0ϖϖ˙']1ϖφ[ρ0ϖφ˙'+ρ'ϖφ˙0]z[ρ0z˙']

ρ't+(φ˙0)ρ'φ

=

1ϖϖ[ρ0ϖϖ˙']1ϖφ[ρ0ϖφ˙']z[ρ0z˙'].

Summary[edit]

Set of Linearized Principal Governing Equations in Cylindrical Coordinates

Continuity Equation

ρ't+(φ˙0)ρ'φ

=

1ϖϖ[ρ0ϖϖ˙']1ϖφ[ρ0ϖφ˙']z[ρ0z˙'].

ϖ Component of Euler Equation

ϖ˙'t+(φ˙0)ϖ˙'φ2ϖ(φ˙0φ˙')

=

ϖ(P'ρ0)Φ'ϖ

φ Component of Euler Equation

(ϖφ˙')t+(φ˙0)(ϖφ˙')φ+ϖ˙'ϖ[(ϖ2φ˙0)ϖ]

=

1ϖ[φ(P'ρ0)+Φ'φ]

z Component of Euler Equation

z˙'t+(φ˙0)z˙'φ

=

z(P'ρ0)Φ'z

Adiabatic Form of the 1st Law of Thermodynamics

P'P0

=

γρ'ρ0

Poisson Equation

2Φ'

=

4πGρ'

See Also[edit]

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