Magnetic shear: Difference between revisions
No edit summary |
|||
Line 35: | Line 35: | ||
where | where | ||
:<math>\vec{h} = \frac{\vec{\nabla} \psi}{|\vec{\nabla} \psi|} \times \vec{ | :<math>\vec{h} = \frac{\vec{\nabla} \psi}{|\vec{\nabla} \psi|} \times \frac{\vec{B}}{|\vec{B}|}</math> | ||
== References == | == References == | ||
<references /> | <references /> |
Revision as of 17:45, 11 October 2009
The shear of a vector field F is
Thus, in 3 dimensions, the shear is a 3 x 3 tensor.
Rotational transform
In the context of magnetic confinement, and assuming the existence of toroidally nested magnetic flux surfaces, the only relevant variation of the direction of the magnetic field is the radial gradient of the rotational transform (field line pitch). The latter is defined as
where ψ is the poloidal magnetic flux, and φ the toroidal magnetic flux. Thus, ι/2π is the mean number of toroidal transits (n) divided by the mean number of poloidal transits (m) of a field line on a flux surface. In tokamak research, the quantity q = 2π/ι is preferred (called the "safety factor").
Global magnetic shear
The global magnetic shear is defined as
High values of magnetic shear provide stability, since the radial extension of helically resonant modes is reduced. Negative shear also provides stability, possibly because convective cells, generated by curvature-driven instabilities, are sheared apart as the field lines twist around the torus. [1]
Local magnetic shear
The local magnetic shear is defined as [2]
where