Internal inductance: Difference between revisions

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On the other hand, the energy contained in the magnetic field produced by the loop is
On the other hand, the energy contained in the magnetic field produced by the loop is
:<math>W = \int{\frac{B^2}{2\mu_0} d\vec r}</math>
:<math>W = \int{\frac{B^2}{2\mu_0} d\vec r}</math>
It can be shown that<ref>P.M. Bellan, ''Fundamentals of Plasma Physics'', Cambridge University Press (2006) ISBN 0521821169</ref><ref>[[:Wikipedia:Inductance]]</ref>
It can be shown that<ref>P.M. Bellan, ''Fundamentals of Plasma Physics'', Cambridge University Press (2006) {{ISBN|0521821169}}</ref><ref>[[:Wikipedia:Inductance]]</ref>
:<math>W = \frac12 L I^2</math>
:<math>W = \frac12 L I^2</math>
The ''internal'' inductance is defined as the part of the inductance obtained by integrating over the plasma volume ''P'' <ref name="Freidberg">J.P. Freidberg, ''Plasma physics and fusion energy'', Cambridge University Press (2007) ISBN 0521851076</ref>:
 
== Internal inductance of a plasma ==
 
The ''internal'' inductance is defined as the part of the inductance obtained by integrating over the plasma volume ''P'' <ref name="Freidberg">J.P. Freidberg, ''Plasma physics and fusion energy'', Cambridge University Press (2007) {{ISBN|0521851076}}</ref>:
:<math>\frac12 L_i I^2 = \int_P{\frac{B^2}{2\mu_0} d\vec r}</math>
:<math>\frac12 L_i I^2 = \int_P{\frac{B^2}{2\mu_0} d\vec r}</math>
Its complement is the external inductance (''L = L<sub>i</sub> + L<sub>e</sub>'').
Its complement is the external inductance (''L = L<sub>i</sub> + L<sub>e</sub>'').
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In a [[tokamak]], the field produced by the plasma current is the ''poloidal'' magnetic field ''B<sub>&theta;<sub>'', so only this field component enters the definition.
In a [[tokamak]], the field produced by the plasma current is the ''poloidal'' magnetic field ''B<sub>&theta;<sub>'', so only this field component enters the definition.
In this context, it is common to use the ''normalized'' internal inductance<ref>K. Miyamoto, ''Plasma Physics and Controlled Nuclear Fusion'', Springer-Verlag (2005) ISBN 3540242171</ref>
In this context, it is common to use the ''normalized'' internal inductance<ref>K. Miyamoto, ''Plasma Physics and Controlled Nuclear Fusion'', Springer-Verlag (2005) {{ISBN|3540242171}}</ref>
:<math>l_i = \frac{2 \pi \int_P{B_\theta^2(\rho) \rho d\rho}}{\pi a^2 B_\theta^2(a)} = \frac{\left \langle B_\theta^2 \right \rangle}{B_\theta^2(a)}</math>
:<math>l_i = \frac{\left \langle B_\theta^2 \right \rangle_P}{B_\theta^2(a)} = \frac{2 \pi \int_0^a{B_\theta^2(\rho) \rho d\rho}}{\pi a^2 B_\theta^2(a)}</math>
(for circular cross section plasmas with [[Toroidal coordinates|minor radius]] ''a''), where angular brackets signify taking a mean value.
(for circular cross section plasmas with [[Toroidal coordinates|minor radius]] ''a''), where angular brackets signify taking a mean value.


Alternatively, sometimes the internal inductance per unit length is used, defined as<ref name="Freidberg"/>
Using Ampère's Law (<math>2 \pi a B_\theta(a) = \mu_0 I</math>), one obtains <ref name="Freidberg"/>
:<math>l_i' = \frac{L_i}{2\pi R_0}\frac{4\pi}{\mu_0} = \frac{2L_i}{\mu_0R_0}</math>
:<math>l_i = \frac{L_i}{2\pi R_0}\frac{4\pi}{\mu_0} = \frac{2L_i}{\mu_0R_0}</math>
where ''R<sub>0</sub>'' is the [[Toroidal coordinates|major radius]], and similar for the external inductance.
where ''R<sub>0</sub>'' is the [[Toroidal coordinates|major radius]], and similar for the external inductance.
Using Ampère's Law (<math>2 \pi a B_\theta(a) = \mu_0 I</math>), one finds <math>l_i = 2 \pi l_i'</math>.


The value of the normalized internal inductance depends on the current density profile in the toroidal plasma (as it produces the <math>B_\theta(\rho)</math> profile).
The [[ITER]] design uses the following approximate definition:<ref>[[doi:10.1088/0029-5515/48/12/125002|G.L. Jackson, T.A. Casper, T.C. Luce, et al., ''ITER startup studies in the DIII-D tokamak'', Nucl. Fusion '''48''', 12 (2008) 125002]]</ref>
:<math>l_i(3) = \frac{2 V \left \langle B_\theta^2 \right \rangle}{\mu_0^2I^2 R_0}</math>
which is equal to <math>l_i</math> assuming the plasma has a perfect toroidal shape, <math>V = \pi a^2 \cdot 2 \pi R_0</math>.<ref>[[Effective plasma radius]]</ref>
 
== Relation to current profile ==
 
The value of the normalized internal inductance depends on the current density profile in the toroidal plasma (as it produces the <math>B_\theta(\rho)</math> profile): a small value of <math>l_i</math> corresponds to a broad current profile.


== References ==
== References ==
<references />
<references />

Latest revision as of 11:30, 26 January 2023

The self-inductance of a current loop is defined as the ratio of the magnetic flux Φ traversing the loop and its current I:

The flux is found by integrating the field over the loop area:

On the other hand, the energy contained in the magnetic field produced by the loop is

It can be shown that[1][2]

Internal inductance of a plasma

The internal inductance is defined as the part of the inductance obtained by integrating over the plasma volume P [3]:

Its complement is the external inductance (L = Li + Le).

Normalized internal inductance

In a tokamak, the field produced by the plasma current is the poloidal magnetic field Bθ, so only this field component enters the definition. In this context, it is common to use the normalized internal inductance[4]

(for circular cross section plasmas with minor radius a), where angular brackets signify taking a mean value.

Using Ampère's Law (), one obtains [3]

where R0 is the major radius, and similar for the external inductance.

The ITER design uses the following approximate definition:[5]

which is equal to assuming the plasma has a perfect toroidal shape, .[6]

Relation to current profile

The value of the normalized internal inductance depends on the current density profile in the toroidal plasma (as it produces the profile): a small value of corresponds to a broad current profile.

References

  1. P.M. Bellan, Fundamentals of Plasma Physics, Cambridge University Press (2006) ISBN 0521821169
  2. Wikipedia:Inductance
  3. 3.0 3.1 J.P. Freidberg, Plasma physics and fusion energy, Cambridge University Press (2007) ISBN 0521851076
  4. K. Miyamoto, Plasma Physics and Controlled Nuclear Fusion, Springer-Verlag (2005) ISBN 3540242171
  5. G.L. Jackson, T.A. Casper, T.C. Luce, et al., ITER startup studies in the DIII-D tokamak, Nucl. Fusion 48, 12 (2008) 125002
  6. Effective plasma radius