Flux coordinates: Difference between revisions
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Flux coordinates in the context of magnetic confinement fusion (MCF) is a set of coordinate functions adapted to the shape of the [[Flux surface|flux surfaces]] of the confining magnetic trap. They consist of one flux label, often termed <math>\psi</math> and two angle-like variables <math>\theta, \phi</math> whose constant contours on the flux <math>(\psi({\mathbf x}) = {\textrm constant})</math> surfaces close either poloidaly (<math>\phi</math>) or toroidallly (<math>\theta</math>). | |||
In this coordinates, equilibrium vector fields like the magnetic field <math>{\mathbf B}</math> or current density <math>{\mathbf j}</math> have simplified expressions. A particular kind of flux coordinates, generally called [[Flux_coordinates#Magnetic_coordinates|magnetic coordinates]], simplify the <math>{\mathbf B}</math>-field expression further by making field lines look straight in the <math>(\theta, \phi)</math> plane of that family of coordinates. Some popular choices of magnetic coordinate systems are [[Boozer coordinates]] and [[Hamada coordinates]]. | |||
[[Image:CurrentIntegrationCirtuits.png|400px|thumb|right|alt=Flux surface and a <math>\theta</math>-curve and <math>\phi</math>-curve.|Sample flux surface of the [[TJ-II]] [[Stellarator|stellarator]] and a <math>\theta</math>-curve (yellow) and <math>\phi</math>-curve (red).]] | |||
== General curvilinear coordinates == | == General curvilinear coordinates == | ||
Here we briefly review the basic definitions of a general [[:Wikipedia:Curvilinear coordinates | curvilinear coordinate system]] for later convenience when discussing toroidal flux coordinates and magnetic coordinates. | Here we briefly review the basic definitions of a general [[:Wikipedia:Curvilinear coordinates | curvilinear coordinate system]] for later convenience when discussing toroidal flux coordinates and magnetic coordinates. | ||
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\to | \to | ||
\mathbf{e}_i\cdot\mathbf{e}^j | \mathbf{e}_i\cdot\mathbf{e}^j | ||
= \delta_{i}^{j} | = \delta_{i}^{j}~, | ||
= \frac{\mathbf{e}^j\times\mathbf{e}^k}{ | </math> | ||
and therefore relates to the contravariant vectors as | |||
:<math> | |||
\mathbf{e}_i | |||
= \frac{\mathbf{e}^j\times\mathbf{e}^k}{\mathbf{e}^i\cdot\mathbf{e}^j\times\mathbf{e}^k} | |||
= \sqrt{g}\;\mathbf{e}^j\times\mathbf{e}^k ~, | = \sqrt{g}\;\mathbf{e}^j\times\mathbf{e}^k ~, | ||
</math> | </math> | ||
where <math>(i,j,k)</math> are cyclic permutations of <math>(1,2,3)</math> and we have used the notation <math>(u^1, u^2, u^3) = (\psi,\theta,\phi)</math>. The Jacobian <math>\sqrt{g}</math> is defined below. | where <math>(i,j,k)</math> are cyclic permutations of <math>(1,2,3)</math> and we have used the notation <math>(u^1, u^2, u^3) = (\psi,\theta,\phi)</math>. The Jacobian <math>\sqrt{g}</math> is defined below. Similarly | ||
:<math> | |||
\mathbf{e}^i = \frac{\mathbf{e}_j\times\mathbf{e}_k}{\sqrt{g}} ~. | |||
</math> | |||
Any vector field <math>\mathbf{B}</math> can be represented as | Any vector field <math>\mathbf{B}</math> can be represented as | ||
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</math> | </math> | ||
It can be seen that <ref name='Dhaeseleer'></ref> <math>g \equiv \det(g_{ij}) = J^2 \Rightarrow J = \sqrt{g}</math> | It can be seen that <ref name='Dhaeseleer'></ref> <math>g \equiv \det(g_{ij}) = J^2 \Rightarrow J = \sqrt{g}</math> | ||
=== Some surface elements === | |||
Consider a surface defined by a constant value of <math>\phi</math>. Then, the surface element is | |||
:<math> | |||
d{\mathbf S}_\phi = \mathbf{e}_\psi\times\mathbf{e}_\theta d\psi d\theta = \sqrt{g}\, \nabla\phi d\psi d\theta . | |||
</math> | |||
As for a surface defined by a constant value of <math>\theta</math>: | |||
:<math> | |||
d{\mathbf S}_\theta = \mathbf{e}_\phi\times\mathbf{e}_\psi d\psi d\phi = \sqrt{g}\, \nabla\theta d\psi d\phi , | |||
</math> | |||
or a constant <math>\psi</math> surface: | |||
:<math> | |||
d{\mathbf S}_\psi = \mathbf{e}_\theta\times\mathbf{e}_\phi d\theta d\phi = \sqrt{g}\, \nabla\psi d\theta d\phi . | |||
</math> | |||
=== Gradient, Divergence and Curl in curvilinear coordinates === | === Gradient, Divergence and Curl in curvilinear coordinates === | ||
The gradient of a function f is naturally given in the contravariant | The gradient of a function f is naturally given in the contravariant basis vectors: | ||
:<math> | :<math> | ||
\nabla f = \frac{\partial f}{\partial u^i}\nabla u^i = \frac{\partial f}{\partial u^i}\mathbf{e}^i~. | \nabla f = \frac{\partial f}{\partial u^i}\nabla u^i = \frac{\partial f}{\partial u^i}\mathbf{e}^i~. | ||
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while the curl is | while the curl is | ||
:<math> | :<math> | ||
\nabla\times\mathbf{A} = \frac{\ | \nabla\times\mathbf{A} = \frac{\varepsilon^{ijk}}{\sqrt{g}}\frac{\partial A_j}{\partial u^i}\mathbf{e}_k \Rightarrow | ||
\left(\nabla\times\mathbf{A}\right)^k = \frac{\varepsilon^{ijk}}{\sqrt{g}}\frac{\partial A_j}{\partial u^i} | |||
</math> | </math> | ||
given in terms of the covariant base vectors, where <math>\ | given in terms of the covariant base vectors, where <math>\varepsilon^{ijk}</math> is the [[::Wikipedia:Levi-Civita symbol| Levi-Civita]] symbol. | ||
== Flux coordinates == | == Flux coordinates == | ||
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=== Flux Surface Average === | === Flux Surface Average === | ||
The | The Flux Surface Average (FSA) of a function <math>\Phi</math> is defined as the limit | ||
:<math> | :<math> | ||
\langle\Phi\rangle = \lim_{\delta \mathcal{V} \to 0}\frac{1}{\delta \mathcal{V}}\int_{\delta \mathcal{V}} \Phi\; d\mathcal{V} | \langle\Phi\rangle = \lim_{\delta \mathcal{V} \to 0}\frac{1}{\delta \mathcal{V}}\int_{\delta \mathcal{V}} \Phi\; d\mathcal{V} | ||
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==== Useful properties of FSA ==== | ==== Useful properties of FSA ==== | ||
Some useful properties of the FSA are | Some useful properties of the FSA are | ||
*<math> \langle \mathbf{B}\cdot\nabla f \rangle = \langle \nabla\cdot(\mathbf{B} f) \rangle = 0~,\qquad \forall~ \mathrm{single~valued~} f(\mathbf{x}), ~ \mathrm{if}~ \nabla\cdot\mathbf{B} = 0 ~\mathrm{and}~ \nabla \psi\cdot\mathbf{B} = 0 </math> | |||
*<math> \langle\nabla\cdot\Gamma\rangle = \frac{d}{dV}\langle\Gamma\cdot\nabla V\rangle = \frac{1}{V'}\frac{d}{d\psi}V'\langle\Gamma\cdot\nabla \psi\rangle</math> | |||
*<math> \int_{\mathcal{V}}\nabla\cdot\Gamma\; d\mathcal{V} = \ | The two identities above are the basic simplifying properties of the FSA: The first cancels the contribution of 'conservative forces' like the pressure gradient or electrostatic electric fields. The second reduces the number of spatial variables to only the radial one. Further, it is possible to show that, if <math>\nabla\cdot\Gamma = 0</math> then <math>\langle\Gamma\cdot\nabla V\rangle = 0</math> and not simply constant as the above suggests. This can be seen by simply using Gauss' theorem | ||
*<math> \int_{\mathcal{V}}\nabla\cdot\Gamma\; d\mathcal{V} = | |||
\int_{S(\mathcal{V})}\Gamma\cdot\nabla V \frac{dS}{|\nabla V|} = | |||
\langle\Gamma\cdot\nabla V\rangle \qquad \mathrm{where~} \mathcal{V} \mathrm{~is~the~volume~enclosed~by~a~flux~surface.} | |||
</math> | |||
The FSA relates to the conventional volume integral between two surfaces labelled by their volumes <math>V_1</math> and <math>V_2</math> as | |||
*<math> \int_{\mathcal{V}(V_1<V<V_2)} f\; d\mathcal{V} = \int_{V_1}^{V_2} \langle f \rangle\; dV | |||
</math> | |||
whereas the conventional surface integral over a <math>\psi = constant</math> is | |||
*<math> \int_{S(\psi)} f\; dS = \langle f |\nabla V| \rangle | |||
</math> | </math> | ||
Other useful properties are | |||
*<math> \langle \nabla \psi\cdot\nabla\times \mathbf{A} \rangle = -\langle \nabla\cdot( \nabla\psi\times\mathbf{A}) \rangle = 0~. | *<math> \langle \nabla \psi\cdot\nabla\times \mathbf{A} \rangle = -\langle \nabla\cdot( \nabla\psi\times\mathbf{A}) \rangle = 0~. | ||
</math> | </math> | ||
*<math> \langle \mathbf{B}\cdot\nabla \theta\rangle =2\pi\frac{d\Psi_{pol}}{dV} \qquad (\mathrm{Note:}~ \theta(\mathbf{x})~\mathrm{is~not~single~valued}) | *<math> \langle \mathbf{B}\cdot\nabla \theta\rangle =2\pi\frac{d\Psi_{pol}}{dV} \qquad \mathrm{for~any~poloidal~ angle~} \theta ~ (\mathrm{Note:}~ \theta(\mathbf{x})~\mathrm{is~not~single~valued}) | ||
</math> | </math> | ||
*<math> \langle \mathbf{B}\cdot\nabla \phi\rangle =2\pi\frac{d\Psi_{tor}}{dV} \qquad (\mathrm{Note:}~ \phi(\mathbf{x})~\mathrm{is~not~single~valued}) | *<math> \langle \mathbf{B}\cdot\nabla \phi\rangle =2\pi\frac{d\Psi_{tor}}{dV} \qquad \mathrm{for~any~toroidal~ angle~} \phi ~ (\mathrm{Note:}~ \phi(\mathbf{x})~\mathrm{is~not~single~valued}) | ||
</math> | </math> | ||
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[[Image:CurrentIntegrationCirtuits.png|256px|thumb|right|alt=Sample integration circuits for the definitions of currents.|Sample integration circuits for the current definitions.]] | [[Image:CurrentIntegrationCirtuits.png|256px|thumb|right|alt=Sample integration circuits for the definitions of currents.|Sample integration circuits for the current definitions.]] | ||
[[Image:CurrentIntegrationCirtuitsPoloidalCurrent.png|256px|thumb|right|alt=Sample surface for the definition of the current though a disc.|Sample surface for the definition of the current though a disc. Note that only the current of more external surfaces contribute to the flux of charge through the surface.]] | [[Image:CurrentIntegrationCirtuitsPoloidalCurrent.png|256px|thumb|right|alt=Sample surface for the definition of the current though a disc.|Sample surface for the definition of the current though a disc. Note that only the current of more external surfaces (those enclosing the one drawn here) contribute to the flux of charge through the surface.]] | ||
The functional dependence on the angular variables is again motivated by the single-valuedness of the magnetic field. The particular form of the coefficients can be obtained noting that | Note that <math>I</math> is not the current but <math>\mu_0</math> times the current. The functional dependence on the angular variables is again motivated by the single-valuedness of the magnetic field. The particular form of the coefficients can be obtained noting that | ||
:<math> | :<math> | ||
\int_S \mu_0\mathbf{j}\cdot d\mathbf{S} | \int_S \mu_0\mathbf{j}\cdot d\mathbf{S} | ||
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</math> | </math> | ||
If we now | If we now choose a ''toroidal'' circuit <math>(\Delta\theta = 0, \Delta\phi = 2\pi)</math> we get | ||
:<math> | :<math> | ||
I_{pol}^d = \int_S \mu_0\mathbf{j}\cdot d\mathbf{S}\; ; ~\mathrm{with}~ \partial S ~\mathrm{such~that}~ (\Delta\theta = 0, \Delta\phi = 2\pi)~. | I_{pol}^d = \int_S \mu_0\mathbf{j}\cdot d\mathbf{S}\; ; ~\mathrm{with}~ \partial S ~\mathrm{such~that}~ (\Delta\theta = 0, \Delta\phi = 2\pi)~. | ||
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Magnetic coordinates are a particular type of flux coordinates in which the magnetic field lines are straight lines. In mathematical terms this implies that the periodic part of the magnetic field's stream function is zero in these coordinates so the magnetic field reads | Magnetic coordinates are a particular type of flux coordinates in which the magnetic field lines are straight lines. In mathematical terms this implies that the periodic part of the magnetic field's stream function is zero in these coordinates so the magnetic field reads | ||
:<math> | :<math> | ||
\mathbf{B} = \nabla\psi\times \left( \frac{\Psi_{tor}'}{2\pi}\theta_f | \mathbf{B} = \nabla\psi\times \nabla\left( \frac{\Psi_{tor}'}{2\pi}\theta_f | ||
- \frac{\Psi_{pol}'}{2\pi}\phi_f \right) | - \frac{\Psi_{pol}'}{2\pi}\phi_f \right) | ||
= \frac{\Psi_{pol}'}{2\pi\sqrt{g}}\mathbf{e}_\theta + \frac{\Psi_{tor}'}{2\pi\sqrt{g}}\mathbf{e}_\phi~. | = \frac{\Psi_{pol}'}{2\pi\sqrt{g}}\mathbf{e}_\theta + \frac{\Psi_{tor}'}{2\pi\sqrt{g}}\mathbf{e}_\phi~. | ||
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<math>\iota</math> being the [[rotational transform]]. In a magnetic coordinate system the ''poloidal'' <math> \mathbf{B}_P = B^\theta\mathbf{e}_\theta </math> and ''toroidal'' <math> \mathbf{B}_T = B^\phi\mathbf{e}_\phi</math> components of the magnetic field are individually divergence-less. | <math>\iota</math> being the [[rotational transform]]. In a magnetic coordinate system the ''poloidal'' <math> \mathbf{B}_P = B^\theta\mathbf{e}_\theta </math> and ''toroidal'' <math> \mathbf{B}_T = B^\phi\mathbf{e}_\phi</math> components of the magnetic field are individually divergence-less. | ||
From the above general form of <math> \mathbf{B} </math> in magnetic coordinates it is easy to obtain the following identities valid for any magnetic coordinate system | |||
:<math> | |||
\mathbf{e}_\theta\times\mathbf{B} =\frac{1}{2\pi}\nabla\Psi_{tor}~, | |||
</math> | |||
:<math> | |||
\mathbf{e}_\phi\times\mathbf{B} = -\frac{1}{2\pi}\nabla\Psi_{pol} ~. | |||
</math> | |||
=== Transforming between Magnetic coordinates systems === | === Transforming between Magnetic coordinates systems === | ||
There are infinitely many systems of magnetic coordinates. Any transformation of the angles of the from | There are infinitely many systems of magnetic coordinates. Any transformation of the angles of the from | ||
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(\Psi_{pol}'\partial_{\theta_f} + \Psi_{tor}'\partial_{\phi_f}) G = \frac{\sqrt{g_f}}{\sqrt{g_F}} - 1~. | (\Psi_{pol}'\partial_{\theta_f} + \Psi_{tor}'\partial_{\phi_f}) G = \frac{\sqrt{g_f}}{\sqrt{g_F}} - 1~. | ||
</math> | </math> | ||
which can be turned into an algebraic equation on the | which can be turned into an algebraic equation on the Fourier components of <math>G</math> | ||
:<math> | :<math> | ||
G_{ | G_{mn} = \frac{-i}{\Psi_{pol}'m + \Psi_{tor}'n}\left(\frac{\sqrt{g_f}}{\sqrt{g_F}}\right)_{mn}~. | ||
</math> | </math> | ||
where | where | ||
:<math> | :<math> | ||
G(\psi, \theta_f, \phi_f) = \sum_{n | G(\psi, \theta_f, \phi_f) = \sum_{m,n} G_{mn}(\psi) e^{i(m\theta_f + n\phi_f)} | ||
</math> | </math> | ||
and <math>G_{00} = 0 </math>. | and <math>G_{00} = 0 </math> guarantees periodicity is preserved. | ||
Particular choices of G can be made so as to simplify the description of other fields. The most commonly used magnetic coordinate systems are: | Particular choices of G can be made so as to simplify the description of other fields. The most commonly used magnetic coordinate systems are: | ||
<ref name='Dhaeseleer'>W.D. D'haeseleer, ''Flux coordinates and magnetic field structure: a guide to a fundamental tool of plasma theory'', Springer series in computational physics, Springer-Verlag (1991) ISBN 3540524193</ref> | <ref name='Dhaeseleer'>W.D. D'haeseleer, ''Flux coordinates and magnetic field structure: a guide to a fundamental tool of plasma theory'', Springer series in computational physics, Springer-Verlag (1991) {{ISBN|3540524193}}</ref> | ||
* [[Hamada coordinates]]. <ref>S. Hamada, Nucl. Fusion '''2''' (1962) 23</ref><ref>[ | * [[Hamada coordinates]]. <ref>S. Hamada, Nucl. Fusion '''2''' (1962) 23</ref><ref>[[doi:10.1063/1.1706651|J.M. Greene and J.L Johnson, ''Stability Criterion for Arbitrary Hydromagnetic Equilibria'', Phys. Fluids '''5''' (1962) 510]]</ref> In these coordinates, both the magnetic field lines and current lines corresponding to the [[MHD equilibrium]] are straight. Referring to the definitions above, both <math>\tilde\nu</math> and <math>\tilde\eta</math> are zero in Hamada coordinates. | ||
* [[Boozer coordinates]]. <ref>[ | * [[Boozer coordinates]]. <ref>[[doi:10.1063/1.863297|A.H. Boozer, ''Plasma equilibrium with rational magnetic surfaces'', Phys. Fluids '''24''' (1981) 1999]]</ref><ref>[[doi:10.1063/1.863765|A.H. Boozer, ''Establishment of magnetic coordinates for a given magnetic field'', Phys. Fluids '''25''' (1982) 520]]</ref> In these coordinates, the magnetic field lines corresponding to the [[MHD equilibrium]] are straight and so are the ''diamagnetic lines '', i.e. the integral lines of <math>\nabla\psi\times\mathbf{B}</math>. Referring to the definitions above, both <math>\tilde\nu</math> and <math>\tilde\chi</math> are zero in Boozer coordinates. | ||
== References == | == References == | ||
<references /> | <references /> |
Latest revision as of 11:49, 26 January 2023
Flux coordinates in the context of magnetic confinement fusion (MCF) is a set of coordinate functions adapted to the shape of the flux surfaces of the confining magnetic trap. They consist of one flux label, often termed and two angle-like variables whose constant contours on the flux surfaces close either poloidaly () or toroidallly ().
In this coordinates, equilibrium vector fields like the magnetic field or current density have simplified expressions. A particular kind of flux coordinates, generally called magnetic coordinates, simplify the -field expression further by making field lines look straight in the plane of that family of coordinates. Some popular choices of magnetic coordinate systems are Boozer coordinates and Hamada coordinates.
General curvilinear coordinates
Here we briefly review the basic definitions of a general curvilinear coordinate system for later convenience when discussing toroidal flux coordinates and magnetic coordinates.
Coordinates and basis vectors
Let be a set of euclidean coordinates on and let define a change of coordinates, arbitrary for the time being. We can calculate the contravariant basis vectors as
and the dual covariant basis defined as
and therefore relates to the contravariant vectors as
where are cyclic permutations of and we have used the notation . The Jacobian is defined below. Similarly
Any vector field can be represented as
or
In particular any basis vector . The metric tensor is defined as
The metric tensors can be used to raise or lower indices. Take
so that
Jacobian
The Jacobian of the coordinate transformation is defined as
and that of the inverse transformation
It can be seen that [1]
Some surface elements
Consider a surface defined by a constant value of . Then, the surface element is
As for a surface defined by a constant value of :
or a constant surface:
Gradient, Divergence and Curl in curvilinear coordinates
The gradient of a function f is naturally given in the contravariant basis vectors:
The divergence of a vector is best expressed in terms of its contravariant components
while the curl is
given in terms of the covariant base vectors, where is the [[::Wikipedia:Levi-Civita symbol| Levi-Civita]] symbol.
Flux coordinates
A flux coordinate set is one that includes a flux surface label as a coordinate. A flux surface label is a function that is constant and single valued on each flux surface. In our naming of the general curvilinear coordinates we have already adopted the usual flux coordinate convention for toroidal equilibrium with nested flux surfaces, where is the flux surface label and are -periodic poloidal and toroidal-like angles.
Different flux surface labels can be chosen like toroidal or poloidal magnetic fluxes or the volume contained within the flux surface . By single valued we mean to ensure that any flux label is a monotonous function of any other flux label , so that the function is invertible at least in a volume containing the region of interest. We will denote a generic flux surface label by .
To avoid ambiguity in the sign of line and surface integrals we impose , the toroidal angle increases in the clockwise direction when seen from above and the poloidal angle increases such that .
Flux Surface Average
The Flux Surface Average (FSA) of a function is defined as the limit
where is the volume confined between two flux surfaces. It is therefore a volume average over an infinitesimal spatial region rather than a surface average. To avoid confusion, we denote volume elements or domains with the calligraphic . Capital is reserved for the flux label (coordinate) defined as the volume within a flux surface.
Introducing the differential volume element
or, noting that , we have and we get to a more practical form of the Flux Surface Average
Note that , so the FSA is a surface integral weighted by :
Applying Gauss' theorem to the definition of FSA we get to the identity
Useful properties of FSA
Some useful properties of the FSA are
The two identities above are the basic simplifying properties of the FSA: The first cancels the contribution of 'conservative forces' like the pressure gradient or electrostatic electric fields. The second reduces the number of spatial variables to only the radial one. Further, it is possible to show that, if then and not simply constant as the above suggests. This can be seen by simply using Gauss' theorem
The FSA relates to the conventional volume integral between two surfaces labelled by their volumes and as
whereas the conventional surface integral over a is
Other useful properties are
In the above . Some vector identities are useful to derive the above identities.
Magnetic field representation in flux coordinates
Contravariant Form
Any solenoidal vector field can be written as called its Clebsch representation. For a magnetic field with flux surfaces we can choose, say, to be the flux surface label
Field lines are then given as the intersection of the constant- and constant- surfaces. This form provides a general expression for in terms of the covariant basis vectors of a flux coordinate system
in terms of the function , sometimes referred to as the magnetic field's stream function.
It is worthwhile to note that the Clebsch form of corresponds to a magnetic vector potential (or as they differ only by the Gauge transformation ).
The general form of the stream function is
where is a differentiable function periodic in the two angles. This general form can be derived by using the fact that is a physical function (hence singe-valued). The specific form for the coefficients in front of the secular terms (i.e. the non-periodic terms) can be obtained from the FSA properties .
Covariant Form
If we consider an equilibrium magnetic field such that , where is the current density , then both and and the magnetic field can be written as
where is identified as the magnetic scalar potential. Its general form is
Note that is not the current but times the current. The functional dependence on the angular variables is again motivated by the single-valuedness of the magnetic field. The particular form of the coefficients can be obtained noting that
and choosing an integration circuit contained within a flux surface . Then we get
If we now choose a toroidal circuit we get
here the superscript is meant to indicate the flux is computed through a disc limited by the integration line, as opposed to the ribbon limited by the integration line on one side and the magnetic axis on the other that was used for the definition of poloidal magnetic flux above these lines. Similarly
Contravariant Form of the current density
Taking the curl of the covariant form of the equilibrium current density can be written as
By very similar arguments as those used for (note that both and are solenoidal fields tangent to the flux surfaces) it can be shown that the general expression for is
Note that the poloidal current is now defined through a ribbon and not a disc. The two currents are related as implies
where the integral is performed along the magnetic axis and therefore does not depend on . This can be used to show that a expanded version of is given as
Magnetic coordinates
Magnetic coordinates are a particular type of flux coordinates in which the magnetic field lines are straight lines. In mathematical terms this implies that the periodic part of the magnetic field's stream function is zero in these coordinates so the magnetic field reads
Now a field line is given by and .
Note that, in general, the contravariant components of the magnetic field in a magnetic coordinate system
are not flux functions, but their quotient is
being the rotational transform. In a magnetic coordinate system the poloidal and toroidal components of the magnetic field are individually divergence-less.
From the above general form of in magnetic coordinates it is easy to obtain the following identities valid for any magnetic coordinate system
Transforming between Magnetic coordinates systems
There are infinitely many systems of magnetic coordinates. Any transformation of the angles of the from
where is periodic in the angles, preserves the straightness of the field lines (as can be easily checked by direct substitution). The spatial function , is called the generating function. It can be obtained from a magnetic differential equation if we know the Jacobians of the two magnetic coordinate systems and . In fact taking on any of the transformation of the angles and using the known expressions for the contravariant components of in magnetic coordinates we get
The LHS of this equation has a particularly simple form when one uses a magnetic coordinate system. For instance, if we write in terms of the original magnetic coordinate system we get
which can be turned into an algebraic equation on the Fourier components of
where
and guarantees periodicity is preserved.
Particular choices of G can be made so as to simplify the description of other fields. The most commonly used magnetic coordinate systems are:
[1]
- Hamada coordinates. [2][3] In these coordinates, both the magnetic field lines and current lines corresponding to the MHD equilibrium are straight. Referring to the definitions above, both and are zero in Hamada coordinates.
- Boozer coordinates. [4][5] In these coordinates, the magnetic field lines corresponding to the MHD equilibrium are straight and so are the diamagnetic lines , i.e. the integral lines of . Referring to the definitions above, both and are zero in Boozer coordinates.
References
- ↑ 1.0 1.1 W.D. D'haeseleer, Flux coordinates and magnetic field structure: a guide to a fundamental tool of plasma theory, Springer series in computational physics, Springer-Verlag (1991) ISBN 3540524193
- ↑ S. Hamada, Nucl. Fusion 2 (1962) 23
- ↑ J.M. Greene and J.L Johnson, Stability Criterion for Arbitrary Hydromagnetic Equilibria, Phys. Fluids 5 (1962) 510
- ↑ A.H. Boozer, Plasma equilibrium with rational magnetic surfaces, Phys. Fluids 24 (1981) 1999
- ↑ A.H. Boozer, Establishment of magnetic coordinates for a given magnetic field, Phys. Fluids 25 (1982) 520