Magnetic curvature: Difference between revisions
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The magnetic curvature is defined by | == Field line curvature == | ||
The magnetic field line curvature is defined by | |||
:<math>\vec \kappa = \vec b \cdot \vec \nabla \vec b</math> | :<math>\vec \kappa = \vec b \cdot \vec \nabla \vec b</math> | ||
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and its magnitude is equal to the inverse radius of curvature. | and its magnitude is equal to the inverse radius of curvature. | ||
A plasma is stable against curvature-driven instabilities (e.g., ballooning modes) when | A plasma is stable against curvature-driven [[Plasma instability|instabilities]] (e.g., ballooning modes) when | ||
:<math>\vec \kappa \cdot \vec \nabla p < 0</math> | :<math>\vec \kappa \cdot \vec \nabla p < 0</math> | ||
(good curvature) and unstable otherwise (bad curvature). Here, ''p'' is the pressure. | (good curvature) and unstable otherwise (bad curvature). Here, ''p'' is the pressure. | ||
<ref>[http://link.aps.org/doi/10.1103/RevModPhys.76.1071 A.H. Boozer, ''Physics of | <ref>[http://link.aps.org/doi/10.1103/RevModPhys.76.1071 A.H. Boozer, ''Physics of magnetically confined plasmas'', Rev. Mod. Phys. '''76''' (2004) 1071]</ref> | ||
=== Normal curvature === | |||
The component of the curvature perpendicular to the [[Flux surface|flux surface]] is | |||
:<math>\kappa_N = \vec \kappa \cdot \frac{\vec \nabla \psi}{|\vec \nabla \psi|}</math> | :<math>\kappa_N = \vec \kappa \cdot \frac{\vec \nabla \psi}{|\vec \nabla \psi|}</math> | ||
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Here, ψ is a [[Flux surface|flux surface]] label (such as the poloidal flux). | Here, ψ is a [[Flux surface|flux surface]] label (such as the poloidal flux). | ||
== Geodesic curvature == | === Geodesic curvature === | ||
The component of the field line curvature parallel to the [[Flux surface|flux surface]] is | |||
:<math>\kappa_G = \vec \kappa \cdot \left (\frac{\vec \nabla \psi}{|\vec \nabla \psi|} \times \frac{\vec B}{|\vec B|}\right )</math> | :<math>\kappa_G = \vec \kappa \cdot \left (\frac{\vec \nabla \psi}{|\vec \nabla \psi|} \times \frac{\vec B}{|\vec B|}\right )</math> | ||
== Flux surface curvature == | |||
The tangent plane to any flux surface is spanned up by two tangent vectors: one is the normalized magnetic field vector (discussed above), and the other is | |||
:<math>\vec b_\perp = \frac{\vec \nabla \psi}{|\vec \nabla \psi|} \times \frac{\vec B}{|\vec B|}</math> | |||
The corresponding perpendicular curvature (the curvature of the flux surface in the direction perpendicular to the magnetic field) is | |||
:<math>\vec \kappa_\perp = \vec b_\perp \cdot \vec \nabla \vec b_\perp</math> | |||
and one can again define the corresponding normal and geodesic curvature components in analogy with the above. | |||
== References == | == References == | ||
<references /> | <references /> |
Latest revision as of 19:45, 10 August 2011
Field line curvature
The magnetic field line curvature is defined by
where
is a unit vector along the magnetic field. κ points towards the local centre of curvature of B, and its magnitude is equal to the inverse radius of curvature.
A plasma is stable against curvature-driven instabilities (e.g., ballooning modes) when
(good curvature) and unstable otherwise (bad curvature). Here, p is the pressure. [1]
Normal curvature
The component of the curvature perpendicular to the flux surface is
Here, ψ is a flux surface label (such as the poloidal flux).
Geodesic curvature
The component of the field line curvature parallel to the flux surface is
Flux surface curvature
The tangent plane to any flux surface is spanned up by two tangent vectors: one is the normalized magnetic field vector (discussed above), and the other is
The corresponding perpendicular curvature (the curvature of the flux surface in the direction perpendicular to the magnetic field) is
and one can again define the corresponding normal and geodesic curvature components in analogy with the above.