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-rw-r--r--source/know/concept/alfven-waves/index.md70
1 files changed, 35 insertions, 35 deletions
diff --git a/source/know/concept/alfven-waves/index.md b/source/know/concept/alfven-waves/index.md
index c560c67..31576f3 100644
--- a/source/know/concept/alfven-waves/index.md
+++ b/source/know/concept/alfven-waves/index.md
@@ -10,11 +10,11 @@ layout: "concept"
---
In the [magnetohydrodynamic](/know/concept/magnetohydrodynamics/) description of a plasma,
-we split the velocity $\vb{u}$, electric current $\vb{J}$,
-[magnetic field](/know/concept/magnetic-field/) $\vb{B}$
-and [electric field](/know/concept/electric-field/) $\vb{E}$ like so,
-into a constant uniform equilibrium (subscript $0$)
-and a small unknown perturbation (subscript $1$):
+we split the velocity $$\vb{u}$$, electric current $$\vb{J}$$,
+[magnetic field](/know/concept/magnetic-field/) $$\vb{B}$$
+and [electric field](/know/concept/electric-field/) $$\vb{E}$$ like so,
+into a constant uniform equilibrium (subscript $$0$$)
+and a small unknown perturbation (subscript $$1$$):
$$\begin{aligned}
\vb{u}
@@ -41,7 +41,7 @@ $$\begin{aligned}
\end{aligned}$$
We do this for the momentum equation too,
-assuming that $\vb{J}_0 \!=\! 0$ (to be justified later).
+assuming that $$\vb{J}_0 \!=\! 0$$ (to be justified later).
Note that the temperature is set to zero, such that the pressure vanishes:
$$\begin{aligned}
@@ -49,8 +49,8 @@ $$\begin{aligned}
= \vb{J}_1 \cross \vb{B}_0
\end{aligned}$$
-Where $\rho$ is the uniform equilibrium density.
-We would like an equation for $\vb{J}_1$,
+Where $$\rho$$ is the uniform equilibrium density.
+We would like an equation for $$\vb{J}_1$$,
which is provided by the magnetohydrodynamic form of Ampère's law:
$$\begin{aligned}
@@ -62,14 +62,14 @@ $$\begin{aligned}
\end{aligned}$$
Substituting this into the momentum equation,
-and differentiating with respect to $t$:
+and differentiating with respect to $$t$$:
$$\begin{aligned}
\rho \pdvn{2}{\vb{u}_1}{t}
= \frac{1}{\mu_0} \bigg( \Big( \nabla \cross \pdv{}{\vb{B}1}{t} \Big) \cross \vb{B}_0 \bigg)
\end{aligned}$$
-For which we can use Faraday's law to rewrite $\ipdv{\vb{B}_1}{t}$,
+For which we can use Faraday's law to rewrite $$\ipdv{\vb{B}_1}{t}$$,
incorporating Ohm's law too:
$$\begin{aligned}
@@ -78,7 +78,7 @@ $$\begin{aligned}
= \nabla \cross (\vb{u}_1 \cross \vb{B}_0)
\end{aligned}$$
-Inserting this into the momentum equation for $\vb{u}_1$
+Inserting this into the momentum equation for $$\vb{u}_1$$
thus yields its final form:
$$\begin{aligned}
@@ -86,9 +86,9 @@ $$\begin{aligned}
= \frac{1}{\mu_0} \bigg( \Big( \nabla \cross \big( \nabla \cross (\vb{u}_1 \cross \vb{B}_0) \big) \Big) \cross \vb{B}_0 \bigg)
\end{aligned}$$
-Suppose the magnetic field is pointing in $z$-direction,
-i.e. $\vb{B}_0 = B_0 \vu{e}_z$.
-Then Faraday's law justifies our earlier assumption that $\vb{J}_0 = 0$,
+Suppose the magnetic field is pointing in $$z$$-direction,
+i.e. $$\vb{B}_0 = B_0 \vu{e}_z$$.
+Then Faraday's law justifies our earlier assumption that $$\vb{J}_0 = 0$$,
and the equation can be written as:
$$\begin{aligned}
@@ -96,7 +96,7 @@ $$\begin{aligned}
= v_A^2 \bigg( \Big( \nabla \cross \big( \nabla \cross (\vb{u}_1 \cross \vu{e}_z) \big) \Big) \cross \vu{e}_z \bigg)
\end{aligned}$$
-Where we have defined the so-called **Alfvén velocity** $v_A$ to be given by:
+Where we have defined the so-called **Alfvén velocity** $$v_A$$ to be given by:
$$\begin{aligned}
\boxed{
@@ -105,24 +105,24 @@ $$\begin{aligned}
}
\end{aligned}$$
-Now, consider the following plane-wave ansatz for $\vb{u}_1$,
-with wavevector $\vb{k}$ and frequency $\omega$:
+Now, consider the following plane-wave ansatz for $$\vb{u}_1$$,
+with wavevector $$\vb{k}$$ and frequency $$\omega$$:
$$\begin{aligned}
\vb{u}_1(\vb{r}, t)
&= \vb{u}_1 \exp(i \vb{k} \cdot \vb{r} - i \omega t)
\end{aligned}$$
-Inserting this into the above differential equation for $\vb{u}_1$ leads to:
+Inserting this into the above differential equation for $$\vb{u}_1$$ leads to:
$$\begin{aligned}
\omega^2 \vb{u}_1
= v_A^2 \bigg( \Big( \vb{k} \cross \big( \vb{k} \cross (\vb{u}_1 \cross \vu{e}_z) \big) \Big) \cross \vu{e}_z \bigg)
\end{aligned}$$
-To evaluate this, we rotate our coordinate system around the $z$-axis
-such that $\vb{k} = (0, k_\perp, k_\parallel)$,
-i.e. the wavevector's $x$-component is zero.
+To evaluate this, we rotate our coordinate system around the $$z$$-axis
+such that $$\vb{k} = (0, k_\perp, k_\parallel)$$,
+i.e. the wavevector's $$x$$-component is zero.
Calculating the cross products:
$$\begin{aligned}
@@ -149,7 +149,7 @@ $$\begin{aligned}
\end{aligned}$$
We rewrite this equation in matrix form,
-using that $k_\perp^2 \!+ k_\parallel^2 = k^2 \equiv |\vb{k}|^2$:
+using that $$k_\perp^2 \!+ k_\parallel^2 = k^2 \equiv |\vb{k}|^2$$:
$$\begin{aligned}
\begin{bmatrix}
@@ -161,9 +161,9 @@ $$\begin{aligned}
= 0
\end{aligned}$$
-This has the form of an eigenvalue problem for $\omega^2$,
+This has the form of an eigenvalue problem for $$\omega^2$$,
meaning we must find non-trivial solutions,
-where we cannot simply choose the components of $\vb{u}_1$ to satisfy the equation.
+where we cannot simply choose the components of $$\vb{u}_1$$ to satisfy the equation.
To achieve this, we demand that the matrix' determinant is zero:
$$\begin{aligned}
@@ -171,12 +171,12 @@ $$\begin{aligned}
= 0
\end{aligned}$$
-This equation has three solutions for $\omega^2$,
+This equation has three solutions for $$\omega^2$$,
one for each of its three factors being zero.
-The simplest case $\omega^2 = 0$ is of no interest to us,
+The simplest case $$\omega^2 = 0$$ is of no interest to us,
because we are looking for waves.
-The first interesting case is $\omega^2 = v_A^2 k_\parallel^2$,
+The first interesting case is $$\omega^2 = v_A^2 k_\parallel^2$$,
yielding the following dispersion relation:
$$\begin{aligned}
@@ -188,10 +188,10 @@ $$\begin{aligned}
The resulting waves are called **shear Alfvén waves**.
From the eigenvalue problem, we see that in this case
-$\vb{u}_1 = (u_{1x}, 0, 0)$, meaning $\vb{u}_1 \cdot \vb{k} = 0$:
+$$\vb{u}_1 = (u_{1x}, 0, 0)$$, meaning $$\vb{u}_1 \cdot \vb{k} = 0$$:
these waves are **transverse**.
-The phase velocity $v_p$ and group velocity $v_g$ are as follows,
-where $\theta$ is the angle between $\vb{k}$ and $\vb{B}_0$:
+The phase velocity $$v_p$$ and group velocity $$v_g$$ are as follows,
+where $$\theta$$ is the angle between $$\vb{k}$$ and $$\vb{B}_0$$:
$$\begin{aligned}
v_p
@@ -204,7 +204,7 @@ $$\begin{aligned}
= v_A
\end{aligned}$$
-The other interesting case is $\omega^2 = v_A^2 k^2$,
+The other interesting case is $$\omega^2 = v_A^2 k^2$$,
which leads to so-called **compressional Alfvén waves**,
with the simple dispersion relation:
@@ -215,10 +215,10 @@ $$\begin{aligned}
}
\end{aligned}$$
-Looking at the eigenvalue problem reveals that $\vb{u}_1 = (0, u_{1y}, 0)$,
-meaning $\vb{u}_1 \cdot \vb{k} = u_{1y} k_\perp$,
-so these waves are not necessarily transverse, nor longitudinal (since $k_\parallel$ is free).
-The phase velocity $v_p$ and group velocity $v_g$ are given by:
+Looking at the eigenvalue problem reveals that $$\vb{u}_1 = (0, u_{1y}, 0)$$,
+meaning $$\vb{u}_1 \cdot \vb{k} = u_{1y} k_\perp$$,
+so these waves are not necessarily transverse, nor longitudinal (since $$k_\parallel$$ is free).
+The phase velocity $$v_p$$ and group velocity $$v_g$$ are given by:
$$\begin{aligned}
v_p