MHD equilibrium: Difference between revisions
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The ideal Magneto-HydroDynamic (MHD) equilibrium of a near-Maxwellian magnetically confined plasma is obtained by solving the force balance equation | The static, ideal Magneto-HydroDynamic (MHD) equilibrium of a near-Maxwellian magnetically confined plasma is obtained by solving the force balance equation | ||
:<math>\vec \nabla p = \vec j \times \vec B</math> | :<math>\vec \nabla p = \vec j \times \vec B</math> | ||
| Line 8: | Line 8: | ||
is the plasma current, subject to appropriate boundary conditions. | is the plasma current, subject to appropriate boundary conditions. | ||
The word "ideal" refers to the absence of resistivity. | The word "static" refers to the assumption of zero flow, while the | ||
word "ideal" refers to the absence of resistivity. | |||
Here, the pressure ''p'' is assumed to be isotropic, but a generalization | |||
for non-isotropic pressure is possible. | |||
In two dimensions (assuming axisymmetry), the force balance equation reduces to the | In two dimensions (assuming axisymmetry), the force balance equation reduces to the | ||
Revision as of 11:58, 18 August 2009
The static, ideal Magneto-HydroDynamic (MHD) equilibrium of a near-Maxwellian magnetically confined plasma is obtained by solving the force balance equation
where
is the plasma current, subject to appropriate boundary conditions. The word "static" refers to the assumption of zero flow, while the word "ideal" refers to the absence of resistivity. Here, the pressure p is assumed to be isotropic, but a generalization for non-isotropic pressure is possible.
In two dimensions (assuming axisymmetry), the force balance equation reduces to the Grad-Shafranov equation.
A large number of codes is available to evaluate MHD equilibria.
2-D codes
3-D codes
- VMEC (nested flux surfaces)
- IPEC (nested flux surfaces)
- HINT
- PIES
- SIESTA (islands, fixed boundary)
- BETA