Resistive timescale: Difference between revisions

Latest revision as of 16:28, 11 March 2024

The resistive timescale is the typical time for the diffusion of a magnetic field into a resistive plasma. Based on Faraday's Law,

{\frac {\partial {\vec {B}}}{\partial t}}=-{\vec {\nabla }}\times {\vec {E}},

Ohm's Law,

{\vec {E}}=\eta {\vec {j}},

where η is the resistivity (assumed homogeneous), and Ampère's Law,

{\vec {\nabla }}\times {\vec {B}}=\mu _{0}{\vec {j}},

one immediately derives a diffusion type equation for the magnetic field:

{\frac {\partial {\vec {B}}}{\partial t}}=-{\frac {\eta }{\mu _{0}}}{\vec {\nabla }}\times {\vec {\nabla }}\times {\vec {B}}={\frac {\eta }{\mu _{0}}}\nabla ^{2}{\vec {B}},

since

{\vec {\nabla }}\cdot {\vec {B}}=0.

From this, one can deduce the typical timescale

\tau _{R}\simeq {\frac {\mu _{0}L^{2}}{\eta }}.

Here, L is the typical length scale of the problem, often taken equal to a, the minor radius of the toroidal plasma.

@@ Line 1: / Line 1: @@
 The resistive timescale is the typical time for the diffusion of a magnetic field into a resistive plasma.
 Based on Faraday's Law,
-:<math>\frac{d\vec B}{dt} = \vec \nabla \times \vec E,</math>
+:<math>\frac{\partial \vec B}{\partial t} = -\vec \nabla \times \vec E,</math>
 Ohm's Law,
-:<math>\vec E = \eta \vec j</math>,
+:<math>\vec E = \eta \vec j,</math>
-where ''&eta;'' is the resistivity, and Ampère's Law,
+where ''&eta;'' is the [[:Wikipedia:Spitzer_resistivity|resistivity]] (assumed homogeneous), and Ampère's Law,
-:<math> \vec \nabla \times \vec B = \mu_0 \vec j</math>,
+:<math> \vec \nabla \times \vec B = \mu_0 \vec j,</math>
 one immediately derives a diffusion type equation for the magnetic field:
-:<math>\frac{d\vec B}{dt} = \frac{\eta}{\mu_0} \vec \nabla \times \vec \nabla \times \vec B</math>,
+:<math>\frac{\partial \vec B}{\partial t} = -\frac{\eta}{\mu_0} \vec \nabla \times \vec \nabla \times \vec B = \frac{\eta}{\mu_0} \nabla^2 \vec B,</math>
-from which one can deduce the typical timescale
+since
-:<math> \tau_R \simeq \frac{\mu_0 L^2}{\eta}</math>.
+: <math>\vec \nabla \cdot \vec B = 0.</math>
+From this, one can deduce the typical timescale
+:<math> \tau_R \simeq \frac{\mu_0 L^2}{\eta}.</math>
 Here, ''L'' is the typical length scale of the problem, often taken equal to ''a'', the [[Toroidal coordinates|minor radius]] of the toroidal plasma.
+== See also ==
+* [[:Wikipedia:Lundquist number|Lundquist number]]