From 7c2d27ca89c5b096694b950c766e50df2dc87001 Mon Sep 17 00:00:00 2001
From: Prefetch
Date: Sat, 8 Jan 2022 14:09:13 +0100
Subject: Minor fixes, rename "Ion Sound Wave" and "Ito Process"
---
.../electric-dipole-approximation/index.pdc | 12 +-
.../know/concept/guiding-center-theory/index.pdc | 2 +-
.../concept/hellmann-feynman-theorem/index.pdc | 2 +-
content/know/concept/ion-sound-wave/index.pdc | 265 +++++++++++++++
content/know/concept/ion-sound-waves/index.pdc | 265 ---------------
content/know/concept/ito-calculus/index.pdc | 367 ---------------------
content/know/concept/ito-process/index.pdc | 367 +++++++++++++++++++++
content/know/concept/langmuir-waves/index.pdc | 8 +-
.../know/concept/magnetohydrodynamics/index.pdc | 4 +-
.../time-dependent-perturbation-theory/index.pdc | 6 +-
10 files changed, 649 insertions(+), 649 deletions(-)
create mode 100644 content/know/concept/ion-sound-wave/index.pdc
delete mode 100644 content/know/concept/ion-sound-waves/index.pdc
delete mode 100644 content/know/concept/ito-calculus/index.pdc
create mode 100644 content/know/concept/ito-process/index.pdc
(limited to 'content/know')
diff --git a/content/know/concept/electric-dipole-approximation/index.pdc b/content/know/concept/electric-dipole-approximation/index.pdc
index 96b4fed..265babf 100644
--- a/content/know/concept/electric-dipole-approximation/index.pdc
+++ b/content/know/concept/electric-dipole-approximation/index.pdc
@@ -46,7 +46,7 @@ In an electromagnetic wave,
$\vec{A}$ is oscillating sinusoidally in time and space as follows:
$$\begin{aligned}
- \vec{A}(\vec{r}, t) = \vec{A}_0 \exp\!(i \vec{k} \cdot \vec{r} - i \omega t)
+ \vec{A}(\vec{r}, t) = - i \vec{A}_0 \exp\!(i \vec{k} \cdot \vec{r} - i \omega t)
\end{aligned}$$
The corresponding perturbative
@@ -59,7 +59,7 @@ $$\begin{aligned}
= \vec{E}_0 \exp\!(i \vec{k} \cdot \vec{r} - i \omega t)
\end{aligned}$$
-Where $\vec{E}_0 = i \omega \vec{A}_0$.
+Where $\vec{E}_0 = \omega \vec{A}_0$.
Let us restrict ourselves to visible light,
whose wavelength $2 \pi / k \approx 10^{-6} \:\mathrm{m}$.
Meanwhile, an atomic orbital is on the order of $10^{-10} \:\mathrm{m}$,
@@ -82,7 +82,7 @@ and the electron quantum-mechanically.
Next, we want to convert $\hat{H}_1$
to use the electric field $\vec{E}$ instead of the potential $\vec{A}$.
To do so, we rewrite the momemtum $\vec{P} = m \: \dv*{\vec{r}}{t}$
-and evaluate this in the [Heisenberg picture](/know/concept/heisenberg-picture/):
+and evaluate this in the [interaction picture](/know/concept/interaction-picture/):
$$\begin{aligned}
\matrixel{2}{\dv*{\vec{r}}{t}}{1}
@@ -95,15 +95,15 @@ $$\begin{aligned}
Therefore, $\vec{P} / m = i \omega_0 \vec{r}$,
where $\omega_0 \equiv (E_2 - E_1) / \hbar$ is the resonance frequency of the transition,
-close to which we assume that $\vec{A}$ and $\vec{E}$ are oscillating.
+close to which we assume that $\vec{A}$ and $\vec{E}$ are oscillating, i.e. $\omega \approx \omega_0$.
We thus get:
$$\begin{aligned}
\hat{H}_1(t)
&= - \frac{q}{m} \vec{P} \cdot \vec{A}
- = - i q \omega_0 \vec{r} \cdot \vec{A}_0 \exp\!(- i \omega t)
+ = - (- i i) q \omega_0 \vec{r} \cdot \vec{A}_0 \exp\!(- i \omega t)
\\
- &= - q \vec{r} \cdot \vec{E}_0 \exp\!(- i \omega t)
+ &\approx - q \vec{r} \cdot \vec{E}_0 \exp\!(- i \omega t)
= - \vec{d} \cdot \vec{E}_0 \exp\!(- i \omega t)
\end{aligned}$$
diff --git a/content/know/concept/guiding-center-theory/index.pdc b/content/know/concept/guiding-center-theory/index.pdc
index 12abac0..dee10ba 100644
--- a/content/know/concept/guiding-center-theory/index.pdc
+++ b/content/know/concept/guiding-center-theory/index.pdc
@@ -174,7 +174,7 @@ $$\begin{aligned}
m \dv{\vb{u}_{gc}}{t}
= q \big( \vb{E} + \vb{u}_{gc} \cross \vb{B}
+ \vb{u}_{gc} \cross (\vb{x}_L \cdot \nabla) \vb{B}
- + + \vb{u}_L \cross (\vb{x}_L \cdot \nabla) \vb{B} \big)
+ + \vb{u}_L \cross (\vb{x}_L \cdot \nabla) \vb{B} \big)
\end{aligned}$$
We approximate this by taking the average over a single gyration,
diff --git a/content/know/concept/hellmann-feynman-theorem/index.pdc b/content/know/concept/hellmann-feynman-theorem/index.pdc
index 3b88cd8..1d2fe82 100644
--- a/content/know/concept/hellmann-feynman-theorem/index.pdc
+++ b/content/know/concept/hellmann-feynman-theorem/index.pdc
@@ -74,7 +74,7 @@ to minimize energies with respect to $\lambda$:
$$\begin{aligned}
\boxed{
\nabla_\lambda E_n
- = \matrixel{\psi_m}{\nabla_\lambda \hat{H}}{\psi_n}
+ = \matrixel{\psi_n}{\nabla_\lambda \hat{H}}{\psi_n}
}
\end{aligned}$$
diff --git a/content/know/concept/ion-sound-wave/index.pdc b/content/know/concept/ion-sound-wave/index.pdc
new file mode 100644
index 0000000..5cba1d0
--- /dev/null
+++ b/content/know/concept/ion-sound-wave/index.pdc
@@ -0,0 +1,265 @@
+---
+title: "Ion sound wave"
+firstLetter: "I"
+publishDate: 2021-10-31
+categories:
+- Physics
+- Plasma physics
+
+date: 2021-10-31T09:38:14+01:00
+draft: false
+markup: pandoc
+---
+
+# Ion sound wave
+
+In a plasma, electromagnetic interactions allow
+compressional longitudinal waves to propagate
+at lower temperatures and pressures
+than would be possible in a neutral gas.
+
+We start from the [two-fluid model's](/know/concept/two-fluid-equations/) momentum equations,
+rewriting the [electric field](/know/concept/electric-field/) $\vb{E} = - \nabla \phi$
+and the pressure gradient $\nabla p = \gamma k_B T \nabla n$,
+and arguing that $m_e \approx 0$ because $m_e \ll m_i$:
+
+$$\begin{aligned}
+ m_i n_i \frac{\mathrm{D} \vb{u}_i}{\mathrm{D} t}
+ &= - q_i n_i \nabla \phi - \gamma_i k_B T_i \nabla n_i
+ \\
+ 0
+ &= - q_e n_e \nabla \phi - \gamma_e k_B T_e \nabla n_e
+\end{aligned}$$
+
+Note that we neglect ion-electron collisions,
+and allow for separate values of $\gamma$.
+We split $n_i$, $n_e$, $\vb{u}_i$ and $\phi$ into an equilibrium
+(subscript $0$) and a perturbation (subscript $1$):
+
+$$\begin{aligned}
+ n_i
+ = n_{i0} + n_{i1}
+ \qquad
+ n_e
+ = n_{e0} + n_{e1}
+ \qquad
+ \vb{u}_i
+ = \vb{u}_{i0} + \vb{u}_{i1}
+ \qquad
+ \phi
+ = \phi_0 + \phi_1
+\end{aligned}$$
+
+Where the perturbations $n_{i1}$, $n_{e1}$, $\vb{u}_{i1}$ and $\phi_1$ are tiny,
+and the equilibrium components $n_{i0}$, $n_{e0}$, $\vb{u}_{i0}$ and $\phi_0$
+by definition satisfy:
+
+$$\begin{aligned}
+ \pdv{n_{i0}}{t} = 0
+ \qquad
+ \frac{\mathrm{D} \vb{u}_{i0}}{\mathrm{D} t} = 0
+ \qquad
+ \nabla n_{i0} = \nabla n_{e0} = 0
+ \qquad
+ \vb{u}_{i0} = 0
+ \qquad
+ \phi_0 = 0
+\end{aligned}$$
+
+Inserting this decomposition into the momentum equations
+yields new equations.
+Note that we will implicitly use $\vb{u}_{i0} = 0$
+to pretend that the [material derivative](/know/concept/material-derivative/)
+$\mathrm{D}/\mathrm{D} t$ is linear:
+
+$$\begin{aligned}
+ m_i (n_{i0} \!+\! n_{i1}) \frac{\mathrm{D} (\vb{u}_{i0} \!+\! \vb{u}_{i1})}{\mathrm{D} t}
+ &= - q_i (n_{i0} \!+\! n_{i1}) \nabla (\phi_0 \!+\! \phi_1) - \gamma_i k_B T_i \nabla (n_{i0} \!+\! n_{i1})
+ \\
+ 0
+ &= - q_e (n_{e0} \!+\! n_{e1}) \nabla (\phi_0 \!+\! \phi_1) - \gamma_e k_B T_e \nabla (n_{e0} \!+\! n_{e1})
+\end{aligned}$$
+
+Using the defined properties of the equilibrium components
+$n_{i0}$, $n_{e0}$, $\vb{u}_{i0}$ and $\phi_0$,
+and neglecting all products of perturbations for being small,
+this reduces to:
+
+$$\begin{aligned}
+ m_i n_{i0} \pdv{\vb{u}_{i1}}{t}
+ &= - q_i n_{i0} \nabla \phi_1 - \gamma_i k_B T_i \nabla n_{i1}
+ \\
+ 0
+ &= - q_e n_{e0} \nabla \phi_1 - \gamma_e k_B T_e \nabla n_{e1}
+\end{aligned}$$
+
+Because we are interested in linear waves,
+we make the following plane-wave ansatz:
+
+$$\begin{aligned}
+ n_{i1}(\vb{r}, t)
+ &= n_{i1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
+ \\
+ n_{e1}(\vb{r}, t)
+ &= n_{e1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
+ \\
+ \vb{u}_{i1}(\vb{r}, t)
+ &= \vb{u}_{i1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
+ \\
+ \phi_1(\vb{r}, t)
+ &= \phi_1 \,\,\exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
+\end{aligned}$$
+
+Which we then insert into the momentum equations for the ions and electrons:
+
+$$\begin{aligned}
+ - i \omega m_i n_{i0} \vb{u}_{i1}
+ &= - i \vb{k} q_i n_{i0} \phi_1 - i \vb{k} \gamma_i k_B T_i n_{i1}
+ \\
+ 0
+ &= - i \vb{k} q_e n_{e0} \phi_1 - i \vb{k} \gamma_e k_B T_e n_{e1}
+\end{aligned}$$
+
+The electron equation can easily be rearranged
+to get a relation between $n_{e1}$ and $n_{e0}$:
+
+$$\begin{aligned}
+ i \vb{k} \gamma_e k_B T_e n_{e1}
+ = - i \vb{k} q_e n_{e0} \phi_1
+ \quad \implies \quad
+ n_{e1}
+ = - \frac{q_e \phi_1}{\gamma_e k_B T_e} n_{e0}
+\end{aligned}$$
+
+Due to their low mass, the electrons' heat conductivity
+can be regarded as infinite compared to the ions'.
+In that case, all electron gas compression is isothermal,
+meaning it obeys the ideal gas law $p_e = n_e k_B T_e$, so that $\gamma_e = 1$.
+Note that this yields the first-order term of a Taylor expansion
+of the [Boltzmann relation](/know/concept/boltzmann-relation/).
+
+At equilibrium, quasi-neutrality demands that $n_{i0} = n_{e0} = n_0$,
+so we can rearrange the above relation to $n_0 = - k_B T_e n_{e1} / (q_e \phi_1)$,
+which we insert into the ion equation to get:
+
+$$\begin{gathered}
+ i \omega m_i \frac{k_B T_e n_{e1}}{q_e \phi_1} \vb{u}_{i1}
+ = - i q_i \frac{k_B T_e n_{e1}}{q_e \phi_1} \phi_1 \vb{k} - i \gamma_i k_B T_i n_{i1} \vb{k}
+ \\
+ \implies \qquad
+ \omega m_i \frac{T_e n_{e1}}{q_e \phi_1} \vb{k} \cdot \vb{u}_{i1}
+ = T_e n_{e1} |\vb{k}|^2 - \gamma_i T_i n_{i1} |\vb{k}|^2
+\end{gathered}$$
+
+Where we have taken the dot product with $\vb{k}$,
+and used that $q_i / q_e = -1$.
+In order to simplify this equation,
+we turn to the two-fluid ion continuity relation:
+
+$$\begin{aligned}
+ 0
+ &= \pdv{(n_{i0} \!+\! n_{i1})}{t} + \nabla \cdot \Big( (n_{i0} \!+\! n_{i1}) (\vb{u}_{i0} \!+\! \vb{u}_{i1}) \Big)
+ \approx \pdv{n_{i1}}{t} + n_{i0} \nabla \cdot \vb{u}_{i1}
+\end{aligned}$$
+
+Then we insert our plane-wave ansatz,
+and substitute $n_{i0} = n_0$ as before, yielding:
+
+$$\begin{aligned}
+ 0
+ = - i \omega n_{i1} + i n_{i0} \vb{k} \cdot \vb{u}_{i1}
+ \quad \implies \quad
+ \vb{k} \cdot \vb{u}_{i1}
+ = \omega \frac{n_{i1}}{n_{i0}}
+ = \omega \frac{q_e n_{i1} \phi_1}{k_B T_e n_{e1}}
+\end{aligned}$$
+
+Substituting this in the ion momentum equation
+leads us to a dispersion relation $\omega(\vb{k})$:
+
+$$\begin{gathered}
+ \omega^2 m_i \frac{T_e n_{e1}}{q_e \phi_1} \frac{q_e n_{i1} \phi_1}{k_B T_e n_{e1}}
+ = \omega^2 m_i \frac{n_{i1}}{k_B}
+ = |\vb{k}|^2 \big( T_e n_{e1} - \gamma_i T_i n_{i1} \big)
+ \\
+ \implies \qquad
+ \omega^2
+ = \frac{|\vb{k}|^2}{m_i} \Big( k_B T_e \frac{n_{e1}}{n_{i1}} - \gamma_i k_B T_i \Big)
+\end{gathered}$$
+
+Finally, we would like to find an expression for $n_{e1} / n_{i1}$.
+It cannot be $1$, because then $\phi_1$ could not be nonzero,
+according to [Gauss' law](/know/concept/maxwells-equations/).
+Nevertheless, authors often ignore this fact,
+thereby making the so-called **plasma approximation**.
+We will not, and therefore turn to Gauss' law:
+
+$$\begin{aligned}
+ \varepsilon_0 \nabla \cdot \vb{E}
+ = - \varepsilon_0 \nabla^2 \phi_1
+ = q_i n_i - q_e n_e
+ = - q_e (n_{i1} - n_{e1})
+\end{aligned}$$
+
+One final time, we insert our plane-wave ansatz,
+and use our Boltzmann-like relation between $n_{e1}$ and $n_{e0}$
+to substitute $\phi_1 = - k_B T_e n_{e1} / (q_e n_{e0})$:
+
+$$\begin{gathered}
+ q_e (n_{e1} - n_{i1})
+ = |\vb{k}|^2 \varepsilon_0 \phi_1
+ = - |\vb{k}|^2 \varepsilon_0 \frac{k_B T_e n_{e1}}{q_e n_{e0}}
+ \\
+ \implies \qquad
+ n_{i1}
+ = n_{e1} + |\vb{k}|^2 \varepsilon_0 \frac{k_B T_e n_{e1}}{q_e^2 n_{e0}}
+ = n_{e1} \big( 1 + |\vb{k}|^2 \lambda_{De}^2 \big)
+\end{gathered}$$
+
+Where $\lambda_{De}$ is the electron [Debye length](/know/concept/debye-length/).
+We thus reach the following dispersion relation,
+which governs **ion sound waves** or **ion acoustic waves**:
+
+$$\begin{aligned}
+ \boxed{
+ \omega^2
+ = \frac{|\vb{k}|^2}{m_i} \bigg( \frac{k_B T_e}{1 + |\vb{k}|^2 \lambda_{De}^2} + \gamma_i k_B T_i \bigg)
+ }
+\end{aligned}$$
+
+The aforementioned plasma approximation is valid if $|\vb{k}| \lambda_{De} \ll 1$,
+which is often reasonable,
+in which case this dispersion relation reduces to:
+
+$$\begin{aligned}
+ \omega^2
+ = \frac{|\vb{k}|^2}{m_i} \bigg( k_B T_e + \gamma_i k_B T_i \bigg)
+\end{aligned}$$
+
+The phase velocity $v_s$ of these waves,
+i.e. the speed of sound, is then given by:
+
+$$\begin{aligned}
+ \boxed{
+ v_s
+ = \frac{\omega}{k}
+ = \sqrt{\frac{k_B T_e}{m_i} + \frac{\gamma_i k_B T_i}{m_i}}
+ }
+\end{aligned}$$
+
+Curiously, unlike a neutral gas,
+this velocity is nonzero even if $T_i = 0$,
+meaning that the waves still exist then.
+In fact, usually the electron temperature $T_e$ dominates $T_e \gg T_i$,
+even though the main feature of these waves
+is that they involve ion density fluctuations $n_{i1}$.
+
+
+
+## References
+1. F.F. Chen,
+ *Introduction to plasma physics and controlled fusion*,
+ 3rd edition, Springer.
+2. M. Salewski, A.H. Nielsen,
+ *Plasma physics: lecture notes*,
+ 2021, unpublished.
diff --git a/content/know/concept/ion-sound-waves/index.pdc b/content/know/concept/ion-sound-waves/index.pdc
deleted file mode 100644
index c56188b..0000000
--- a/content/know/concept/ion-sound-waves/index.pdc
+++ /dev/null
@@ -1,265 +0,0 @@
----
-title: "Ion sound waves"
-firstLetter: "I"
-publishDate: 2021-10-31
-categories:
-- Physics
-- Plasma physics
-
-date: 2021-10-31T09:38:14+01:00
-draft: false
-markup: pandoc
----
-
-# Ion sound waves
-
-In a plasma, electromagnetic interactions allow
-compressional longitudinal waves to propagate
-at lower temperatures and pressures
-than would be possible in a neutral gas.
-
-We start from the [two-fluid model's](/know/concept/two-fluid-equations/) momentum equations,
-rewriting the [electric field](/know/concept/electric-field/) $\vb{E} = - \nabla \phi$
-and the pressure gradient $\nabla p = \gamma k_B T \nabla n$,
-and arguing that $m_e \approx 0$ because $m_e \ll m_i$:
-
-$$\begin{aligned}
- m_i n_i \frac{\mathrm{D} \vb{u}_i}{\mathrm{D} t}
- &= - q_i n_i \nabla \phi - \gamma_i k_B T_i \nabla n_i
- \\
- 0
- &= - q_e n_e \nabla \phi - \gamma_e k_B T_e \nabla n_e
-\end{aligned}$$
-
-Note that we neglect ion-electron collisions,
-and allow for separate values of $\gamma$.
-We split $n_i$, $n_e$, $\vb{u}_i$ and $\phi$ into an equilibrium
-(subscript $0$) and a perturbation (subscript $1$):
-
-$$\begin{aligned}
- n_i
- = n_{i0} + n_{i1}
- \qquad
- n_e
- = n_{e0} + n_{e1}
- \qquad
- \vb{u}_i
- = \vb{u}_{i0} + \vb{u}_{i1}
- \qquad
- \phi
- = \phi_0 + \phi_1
-\end{aligned}$$
-
-Where the perturbations $n_{i1}$, $n_{e1}$, $\vb{u}_{i1}$ and $\phi_1$ are tiny,
-and the equilibrium components $n_{i0}$, $n_{e0}$, $\vb{u}_{i0}$ and $\phi_0$
-by definition satisfy:
-
-$$\begin{aligned}
- \pdv{n_{i0}}{t} = 0
- \qquad
- \frac{\mathrm{D} \vb{u}_{i0}}{\mathrm{D} t} = 0
- \qquad
- \nabla n_{i0} = \nabla n_{e0} = 0
- \qquad
- \vb{u}_{i0} = 0
- \qquad
- \phi_0 = 0
-\end{aligned}$$
-
-Inserting this decomposition into the momentum equations
-yields new equations.
-Note that we will implicitly use $\vb{u}_{i0} = 0$
-to pretend that the [material derivative](/know/concept/material-derivative/)
-$\mathrm{D}/\mathrm{D} t$ is linear:
-
-$$\begin{aligned}
- m_i (n_{i0} \!+\! n_{i1}) \frac{\mathrm{D} (\vb{u}_{i0} \!+\! \vb{u}_{i1})}{\mathrm{D} t}
- &= - q_i (n_{i0} \!+\! n_{i1}) \nabla (\phi_0 \!+\! \phi_1) - \gamma_i k_B T_i \nabla (n_{i0} \!+\! n_{i1})
- \\
- 0
- &= - q_e (n_{e0} \!+\! n_{e1}) \nabla (\phi_0 \!+\! \phi_1) - \gamma_e k_B T_e \nabla (n_{e0} \!+\! n_{e1})
-\end{aligned}$$
-
-Using the defined properties of the equilibrium components
-$n_{i0}$, $n_{e0}$, $\vb{u}_{i0}$ and $\phi_0$,
-and neglecting all products of perturbations for being small,
-this reduces to:
-
-$$\begin{aligned}
- m_i n_{i0} \pdv{\vb{u}_{i1}}{t}
- &= - q_i n_{i0} \nabla \phi_1 - \gamma_i k_B T_i \nabla n_{i1}
- \\
- 0
- &= - q_e n_{e0} \nabla \phi_1 - \gamma_e k_B T_e \nabla n_{e1}
-\end{aligned}$$
-
-Because we are interested in linear waves,
-we make the following plane-wave ansatz:
-
-$$\begin{aligned}
- n_{i1}(\vb{r}, t)
- &= n_{i1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
- \\
- n_{e1}(\vb{r}, t)
- &= n_{e1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
- \\
- \vb{u}_{i1}(\vb{r}, t)
- &= \vb{u}_{i1} \exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
- \\
- \phi_1(\vb{r}, t)
- &= \phi_1 \,\,\exp\!(i \vb{k} \cdot \vb{r} - i \omega t)
-\end{aligned}$$
-
-Which we then insert into the momentum equations for the ions and electrons:
-
-$$\begin{aligned}
- - i \omega m_i n_{i0} \vb{u}_{i1}
- &= - i \vb{k} q_i n_{i0} \phi_1 - i \vb{k} \gamma_i k_B T_i n_{i1}
- \\
- 0
- &= - i \vb{k} q_e n_{e0} \phi_1 - i \vb{k} \gamma_e k_B T_e n_{e1}
-\end{aligned}$$
-
-The electron equation can easily be rearranged
-to get a relation between $n_{e1}$ and $n_{e0}$:
-
-$$\begin{aligned}
- i \vb{k} \gamma_e k_B T_e n_{e1}
- = - i \vb{k} q_e n_{e0} \phi_1
- \quad \implies \quad
- n_{e1}
- = - \frac{q_e \phi_1}{\gamma_e k_B T_e} n_{e0}
-\end{aligned}$$
-
-Due to their low mass, the electrons' heat conductivity
-can be regarded as infinite compared to the ions'.
-In that case, all electron gas compression is isothermal,
-meaning it obeys the ideal gas law $p_e = n_e k_B T_e$, so that $\gamma_e = 1$.
-Note that this yields the first-order term of a Taylor expansion
-of the [Boltzmann relation](/know/concept/boltzmann-relation/).
-
-At equilibrium, quasi-neutrality demands that $n_{i0} = n_{e0} = n_0$,
-so we can rearrange the above relation to $n_0 = - k_B T_e n_{e1} / (q_e \phi_1)$,
-which we insert into the ion equation to get:
-
-$$\begin{gathered}
- i \omega m_i \frac{k_B T_e n_{e1}}{q_e \phi_1} \vb{u}_{i1}
- = - i q_i \frac{k_B T_e n_{e1}}{q_e \phi_1} \phi_1 \vb{k} - i \gamma_i k_B T_i n_{i1} \vb{k}
- \\
- \implies \qquad
- \omega m_i \frac{T_e n_{e1}}{q_e \phi_1} \vb{k} \cdot \vb{u}_{i1}
- = T_e n_{e1} |\vb{k}|^2 - \gamma_i T_i n_{i1} |\vb{k}|^2
-\end{gathered}$$
-
-Where we have taken the dot product with $\vb{k}$,
-and used that $q_i / q_e = -1$.
-In order to simplify this equation,
-we turn to the two-fluid ion continuity relation:
-
-$$\begin{aligned}
- 0
- &= \pdv{(n_{i0} \!+\! n_{i1})}{t} + \nabla \cdot \Big( (n_{i0} \!+\! n_{i1}) (\vb{u}_{i0} \!+\! \vb{u}_{i1}) \Big)
- \approx \pdv{n_{i1}}{t} + n_{i0} \nabla \cdot \vb{u}_{i1}
-\end{aligned}$$
-
-Then we insert our plane-wave ansatz,
-and substitute $n_{i0} = n_0$ as before, yielding:
-
-$$\begin{aligned}
- 0
- = - i \omega n_{i1} + i n_{i0} \vb{k} \cdot \vb{u}_{i1}
- \quad \implies \quad
- \vb{k} \cdot \vb{u}_{i1}
- = \omega \frac{n_{i1}}{n_{i0}}
- = \omega \frac{q_e n_{i1} \phi_1}{k_B T_e n_{e1}}
-\end{aligned}$$
-
-Substituting this in the ion momentum equation
-leads us to a dispersion relation $\omega(\vb{k})$:
-
-$$\begin{gathered}
- \omega^2 m_i \frac{T_e n_{e1}}{q_e \phi_1} \frac{q_e n_{i1} \phi_1}{k_B T_e n_{e1}}
- = \omega^2 m_i \frac{n_{i1}}{k_B}
- = |\vb{k}|^2 \big( T_e n_{e1} - \gamma_i T_i n_{i1} \big)
- \\
- \implies \qquad
- \omega^2
- = \frac{|\vb{k}|^2}{m_i} \Big( k_B T_e \frac{n_{e1}}{n_{i1}} - \gamma_i k_B T_i \Big)
-\end{gathered}$$
-
-Finally, we would like to find an expression for $n_{e1} / n_{i1}$.
-It cannot be $1$, because then $\phi_1$ could not be nonzero,
-according to [Gauss' law](/know/concept/maxwells-equations/).
-Nevertheless, authors often ignore this fact,
-thereby making the so-called **plasma approximation**.
-We will not, and therefore turn to Gauss' law:
-
-$$\begin{aligned}
- \varepsilon_0 \nabla \cdot \vb{E}
- = - \varepsilon_0 \nabla^2 \phi_1
- = q_i n_i - q_e n_e
- = - q_e (n_{i1} - n_{e1})
-\end{aligned}$$
-
-One final time, we insert our plane-wave ansatz,
-and use our Boltzmann-like relation between $n_{e1}$ and $n_{e0}$
-to substitute $\phi_1 = - k_B T_e n_{e1} / (q_e n_{e0})$:
-
-$$\begin{gathered}
- q_e (n_{e1} - n_{i1})
- = |\vb{k}|^2 \varepsilon_0 \phi_1
- = - |\vb{k}|^2 \varepsilon_0 \frac{k_B T_e n_{e1}}{q_e n_{e0}}
- \\
- \implies \qquad
- n_{i1}
- = n_{e1} + |\vb{k}|^2 \varepsilon_0 \frac{k_B T_e n_{e1}}{q_e^2 n_{e0}}
- = n_{e1} \big( 1 + |\vb{k}|^2 \lambda_{De}^2 \big)
-\end{gathered}$$
-
-Where $\lambda_{De}$ is the electron [Debye length](/know/concept/debye-length/).
-We thus reach the following dispersion relation,
-which governs **ion sound waves** or **ion acoustic waves**:
-
-$$\begin{aligned}
- \boxed{
- \omega^2
- = \frac{|\vb{k}|^2}{m_i} \bigg( \frac{k_B T_e}{1 + |\vb{k}|^2 \lambda_{De}^2} + \gamma_i k_B T_i \bigg)
- }
-\end{aligned}$$
-
-The aforementioned plasma approximation is valid if $|\vb{k}| \lambda_{De} \ll 1$,
-which is often reasonable,
-in which case this dispersion relation reduces to:
-
-$$\begin{aligned}
- \omega^2
- = \frac{|\vb{k}|^2}{m_i} \bigg( k_B T_e + \gamma_i k_B T_i \bigg)
-\end{aligned}$$
-
-The phase velocity $v_s$ of these waves,
-i.e. the speed of sound, is then given by:
-
-$$\begin{aligned}
- \boxed{
- v_s
- = \frac{\omega}{k}
- = \sqrt{\frac{k_B T_e}{m_i} + \frac{\gamma_i k_B T_i}{m_i}}
- }
-\end{aligned}$$
-
-Curiously, unlike a neutral gas,
-this velocity is nonzero even if $T_i = 0$,
-meaning that the waves still exist then.
-In fact, usually the electron temperature $T_e$ dominates $T_e \gg T_i$,
-even though the main feature of these waves
-is that they involve ion density fluctuations $n_{i1}$.
-
-
-
-## References
-1. F.F. Chen,
- *Introduction to plasma physics and controlled fusion*,
- 3rd edition, Springer.
-2. M. Salewski, A.H. Nielsen,
- *Plasma physics: lecture notes*,
- 2021, unpublished.
diff --git a/content/know/concept/ito-calculus/index.pdc b/content/know/concept/ito-calculus/index.pdc
deleted file mode 100644
index 3d4dd67..0000000
--- a/content/know/concept/ito-calculus/index.pdc
+++ /dev/null
@@ -1,367 +0,0 @@
----
-title: "Itō calculus"
-firstLetter: "I"
-publishDate: 2021-11-06
-categories:
-- Mathematics
-- Stochastic analysis
-
-date: 2021-11-06T14:34:00+01:00
-draft: false
-markup: pandoc
----
-
-# Itō calculus
-
-Given two [stochastic processes](/know/concept/stochastic-process/)
-$F_t$ and $G_t$, consider the following random variable $X_t$,
-where $B_t$ is the [Wiener process](/know/concept/wiener-process/),
-i.e. Brownian motion:
-
-$$\begin{aligned}
- X_t
- = X_0 + \int_0^t F_s \dd{s} + \int_0^t G_s \dd{B_s}
-\end{aligned}$$
-
-Where the latter is an [Itō integral](/know/concept/ito-integral/),
-assuming $G_t$ is Itō-integrable.
-We call $X_t$ an **Itō process** if $F_t$ is locally integrable,
-and the initial condition $X_0$ is known,
-i.e. $X_0$ is $\mathcal{F}_0$-measurable,
-where $\mathcal{F}_t$ is the filtration
-to which $F_t$, $G_t$ and $B_t$ are adapted.
-The above definition of $X_t$ is often abbreviated as follows,
-where $X_0$ is implicit:
-
-$$\begin{aligned}
- \dd{X_t}
- = F_t \dd{t} + G_t \dd{B_t}
-\end{aligned}$$
-
-Typically, $F_t$ is referred to as the **drift** of $X_t$,
-and $G_t$ as its **intensity**.
-Because the Itō integral of $G_t$ is a
-[martingale](/know/concept/martingale/),
-it does not contribute to the mean of $X_t$:
-
-$$\begin{aligned}
- \mathbf{E}[X_t]
- = \int_0^t \mathbf{E}[F_s] \dd{s}
-\end{aligned}$$
-
-Now, consider the following **Itō stochastic differential equation** (SDE),
-where $\xi_t = \dv*{B_t}{t}$ is white noise,
-informally treated as the $t$-derivative of $B_t$:
-
-$$\begin{aligned}
- \dv{X_t}{t}
- = f(X_t, t) + g(X_t, t) \: \xi_t
-\end{aligned}$$
-
-An Itō process $X_t$ is said to satisfy this equation
-if $f(X_t, t) = F_t$ and $g(X_t, t) = G_t$,
-in which case $X_t$ is also called an **Itō diffusion**.
-All Itō diffusions are [Markov processes](/know/concept/markov-process/),
-since only the current value of $X_t$ determines the future,
-and $B_t$ is also a Markov process.
-
-
-## Itō's lemma
-
-Classically, given $y \equiv h(x(t), t)$,
-the chain rule of differentiation states that:
-
-$$\begin{aligned}
- \dd{y}
- = \pdv{h}{t} \dd{t} + \pdv{h}{x} \dd{x}
-\end{aligned}$$
-
-However, for a stochastic process $Y_t \equiv h(X_t, t)$,
-where $X_t$ is an Itō process,
-the chain rule is modified to the following,
-known as **Itō's lemma**:
-
-$$\begin{aligned}
- \boxed{
- \dd{Y_t}
- = \bigg( \pdv{h}{t} + \pdv{h}{x} F_t + \frac{1}{2} \pdv[2]{h}{x} G_t^2 \bigg) \dd{t} + \pdv{h}{x} G_t \dd{B_t}
- }
-\end{aligned}$$
-
-
-
-
-
-
-We start by applying the classical chain rule,
-but we go to second order in $x$.
-This is also valid classically,
-but there we would neglect all higher-order infinitesimals:
-
-$$\begin{aligned}
- \dd{Y_t}
- = \pdv{h}{t} \dd{t} + \pdv{h}{x} \dd{X_t} + \frac{1}{2} \pdv[2]{h}{x} \dd{X_t}^2
-\end{aligned}$$
-
-But here we cannot neglect $\dd{X_t}^2$.
-We insert the definition of an Itō process:
-
-$$\begin{aligned}
- \dd{Y_t}
- &= \pdv{h}{t} \dd{t} + \pdv{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big) + \frac{1}{2} \pdv[2]{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big)^2
- \\
- &= \pdv{h}{t} \dd{t} + \pdv{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big)
- + \frac{1}{2} \pdv[2]{h}{x} \Big( F_t^2 \dd{t}^2 + 2 F_t G_t \dd{t} \dd{B_t} + G_t^2 \dd{B_t}^2 \Big)
-\end{aligned}$$
-
-In the limit of small $\dd{t}$, we can neglect $\dd{t}^2$,
-and as it turns out, $\dd{t} \dd{B_t}$ too:
-
-$$\begin{aligned}
- \dd{t} \dd{B_t}
- &= (B_{t + \dd{t}} - B_t) \dd{t}
- \sim \dd{t} \mathcal{N}(0, \dd{t})
- \sim \mathcal{N}(0, \dd{t}^3)
- \longrightarrow 0
-\end{aligned}$$
-
-However, due to the scaling property of $B_t$,
-we cannot ignore $\dd{B_t}^2$, which has order $\dd{t}$:
-
-$$\begin{aligned}
- \dd{B_t}^2
- &= (B_{t + \dd{t}} - B_t)^2
- \sim \big( \mathcal{N}(0, \dd{t}) \big)^2
- \sim \chi^2_1(\dd{t})
- \longrightarrow \dd{t}
-\end{aligned}$$
-
-Where $\chi_1^2(\dd{t})$ is the generalized chi-squared distribution
-with one term of variance $\dd{t}$.
-
-
-
-The most important application of Itō's lemma
-is to perform coordinate transformations,
-to make the solution of a given Itō SDE easier.
-
-
-## Coordinate transformations
-
-The simplest coordinate transformation is a scaling of the time axis.
-Defining $s \equiv \alpha t$, the goal is to keep the Itō process.
-We know how to scale $B_t$, be setting $W_s \equiv \sqrt{\alpha} B_{s / \alpha}$.
-Let $Y_s \equiv X_t$ be the new variable on the rescaled axis, then:
-
-$$\begin{aligned}
- \dd{Y_s}
- = \dd{X_t}
- &= f(X_t) \dd{t} + g(X_t) \dd{B_t}
- \\
- &= \frac{1}{\alpha} f(Y_s) \dd{s} + \frac{1}{\sqrt{\alpha}} g(Y_s) \dd{W_s}
-\end{aligned}$$
-
-$W_s$ is a valid Wiener process,
-and the other changes are small,
-so this is still an Itō process.
-
-To solve SDEs analytically, it is usually best
-to have additive noise, i.e. $g = 1$.
-This can be achieved using the **Lamperti transform**:
-define $Y_t \equiv h(X_t)$, where $h$ is given by:
-
-$$\begin{aligned}
- \boxed{
- h(x)
- = \int_{x_0}^x \frac{1}{g(y)} \dd{y}
- }
-\end{aligned}$$
-
-Then, using Itō's lemma, it is straightforward
-to show that the intensity becomes $1$.
-Note that the lower integration limit $x_0$ does not enter:
-
-$$\begin{aligned}
- \dd{Y_t}
- &= \bigg( f(X_t) \: h'(X_t) + \frac{1}{2} g^2(X_t) \: h''(X_t) \bigg) \dd{t} + g(X_t) \: h'(X_t) \dd{B_t}
- \\
- &= \bigg( \frac{f(X_t)}{g(X_t)} - \frac{1}{2} g^2(X_t) \frac{g'(X_t)}{g^2(X_t)} \bigg) \dd{t} + \frac{g(X_t)}{g(X_t)} \dd{B_t}
- \\
- &= \bigg( \frac{f(X_t)}{g(X_t)} - \frac{1}{2} g'(X_t) \bigg) \dd{t} + \dd{B_t}
-\end{aligned}$$
-
-Similarly, we can eliminate the drift $f = 0$,
-thereby making the Itō process a martingale.
-This is done by defining $Y_t \equiv h(X_t)$, with $h(x)$ given by:
-
-$$\begin{aligned}
- \boxed{
- h(x)
- = \int_{x_0}^x \exp\!\bigg( \!-\!\! \int_{x_1}^x \frac{2 f(y)}{g^2(y)} \dd{y} \bigg)
- }
-\end{aligned}$$
-
-The goal is to make the parenthesized first term (see above)
-of Itō's lemma disappear, which this $h(x)$ does indeed do.
-Note that $x_0$ and $x_1$ do not enter:
-
-$$\begin{aligned}
- 0
- &= f(x) \: h'(x) + \frac{1}{2} g^2(x) \: h''(x)
- \\
- &= \Big( f(x) - \frac{1}{2} g^2(x) \frac{2 f(x)}{g^2(x)} \Big) \exp\!\bigg( \!-\!\! \int_{x_1}^x \frac{2 f(y)}{g^2(y)} \dd{y} \bigg)
-\end{aligned}$$
-
-
-## Existence and uniqueness
-
-It is worth knowing under what condition a solution to a given SDE exists,
-in the sense that it is finite on the entire time axis.
-Suppose the drift $f$ and intensity $g$ satisfy these inequalities,
-for some known constant $K$ and for all $x$:
-
-$$\begin{aligned}
- x f(x) \le K (1 + x^2)
- \qquad \quad
- g^2(x) \le K (1 + x^2)
-\end{aligned}$$
-
-When this is satisfied, we can find the following upper bound
-on an Itō process $X_t$,
-which clearly implies that $X_t$ is finite for all $t$:
-
-$$\begin{aligned}
- \boxed{
- \mathbf{E}[X_t^2]
- \le \big(X_0^2 + 3 K t\big) \exp\!\big(3 K t\big)
- }
-\end{aligned}$$
-
-
-
-
-
-
-If we define $Y_t \equiv X_t^2$,
-then Itō's lemma tells us that the following holds:
-
-$$\begin{aligned}
- \dd{Y_t}
- = \big( 2 X_t \: f(X_t) + g^2(X_t) \big) \dd{t} + 2 X_t \: g(X_t) \dd{B_t}
-\end{aligned}$$
-
-Integrating and taking the expectation value
-removes the Wiener term, leaving:
-
-$$\begin{aligned}
- \mathbf{E}[Y_t]
- = Y_0 + \mathbf{E}\! \int_0^t 2 X_s f(X_s) + g^2(X_s) \dd{s}
-\end{aligned}$$
-
-Given that $K (1 \!+\! x^2)$ is an upper bound of $x f(x)$ and $g^2(x)$,
-we get an inequality:
-
-$$\begin{aligned}
- \mathbf{E}[Y_t]
- &\le Y_0 + \mathbf{E}\! \int_0^t 2 K (1 \!+\! X_s^2) + K (1 \!+\! X_s^2) \dd{s}
- \\
- &\le Y_0 + \int_0^t 3 K (1 + \mathbf{E}[Y_s]) \dd{s}
- \\
- &\le Y_0 + 3 K t + \int_0^t 3 K \big( \mathbf{E}[Y_s] \big) \dd{s}
-\end{aligned}$$
-
-We then apply the
-[Grönwall-Bellman inequality](/know/concept/gronwall-bellman-inequality/),
-noting that $(Y_0 \!+\! 3 K t)$ does not decrease with time, leading us to:
-
-$$\begin{aligned}
- \mathbf{E}[Y_t]
- &\le (Y_0 + 3 K t) \exp\!\bigg( \int_0^t 3 K \dd{s} \bigg)
- \\
- &\le (Y_0 + 3 K t) \exp\!\big(3 K t\big)
-\end{aligned}$$
-
-
-
-If a solution exists, it is also worth knowing whether it is unique.
-Suppose that $f$ and $g$ satisfy the following inequalities,
-for some constant $K$ and for all $x$ and $y$:
-
-$$\begin{aligned}
- \big| f(x) - f(y) \big| \le K \big| x - y \big|
- \qquad \quad
- \big| g(x) - g(y) \big| \le K \big| x - y \big|
-\end{aligned}$$
-
-Let $X_t$ and $Y_t$ both be solutions to a given SDE,
-but the initial conditions need not be the same,
-such that the difference is initially $X_0 \!-\! Y_0$.
-Then the difference $X_t \!-\! Y_t$ is bounded by:
-
-$$\begin{aligned}
- \boxed{
- \mathbf{E}\big[ (X_t - Y_t)^2 \big]
- \le (X_0 - Y_0)^2 \exp\!\Big( \big(2 K \!+\! K^2 \big) t \Big)
- }
-\end{aligned}$$
-
-
-
-
-
-
-We define $D_t \equiv X_t \!-\! Y_t$ and $Z_t \equiv D_t^2 \ge 0$,
-together with $F_t \equiv f(X_t) \!-\! f(Y_t)$ and $G_t \equiv g(X_t) \!-\! g(Y_t)$,
-such that Itō's lemma states:
-
-$$\begin{aligned}
- \dd{Z_t}
- = \big( 2 D_t F_t + G_t^2 \big) \dd{t} + 2 D_t G_t \dd{B_t}
-\end{aligned}$$
-
-Integrating and taking the expectation value
-removes the Wiener term, leaving:
-
-$$\begin{aligned}
- \mathbf{E}[Z_t]
- = Z_0 + \mathbf{E}\! \int_0^t 2 D_s F_s + G_s^2 \dd{s}
-\end{aligned}$$
-
-The *Cauchy-Schwarz inequality* states that $|D_s F_s| \le |D_s| |F_s|$,
-and then the given fact that $F_s$ and $G_s$ satisfy
-$|F_s| \le K |D_s|$ and $|G_s| \le K |D_s|$ gives:
-
-$$\begin{aligned}
- \mathbf{E}[Z_t]
- &\le Z_0 + \mathbf{E}\! \int_0^t 2 K D_s^2 + K^2 D_s^2 \dd{s}
- \\
- &\le Z_0 + \int_0^t (2 K \!+\! K^2) \: \mathbf{E}[Z_s] \dd{s}
-\end{aligned}$$
-
-Where we have implicitly used that $D_s F_s = |D_s F_s|$
-because $Z_t$ is positive for all $G_s^2$,
-and that $|D_s|^2 = D_s^2$ because $D_s$ is real.
-We then apply the
-[Grönwall-Bellman inequality](/know/concept/gronwall-bellman-inequality/),
-recognizing that $Z_0$ does not decrease with time (since it is constant):
-
-$$\begin{aligned}
- \mathbf{E}[Z_t]
- &\le Z_0 \exp\!\bigg( \int_0^t 2 K \!+\! K^2 \dd{s} \bigg)
- \\
- &\le Z_0 \exp\!\Big( \big( 2 K \!+\! K^2 \big) t \Big)
-\end{aligned}$$
-
-
-
-Using these properties, it can then be shown
-that if all of the above conditions are satisfied,
-then the SDE has a unique solution,
-which is $\mathcal{F}_t$-adapted, continuous, and exists for all times.
-
-
-
-## References
-1. U.H. Thygesen,
- *Lecture notes on diffusions and stochastic differential equations*,
- 2021, Polyteknisk Kompendie.
diff --git a/content/know/concept/ito-process/index.pdc b/content/know/concept/ito-process/index.pdc
new file mode 100644
index 0000000..d27a2fb
--- /dev/null
+++ b/content/know/concept/ito-process/index.pdc
@@ -0,0 +1,367 @@
+---
+title: "Itō process"
+firstLetter: "I"
+publishDate: 2021-11-06
+categories:
+- Mathematics
+- Stochastic analysis
+
+date: 2021-11-06T14:34:00+01:00
+draft: false
+markup: pandoc
+---
+
+# Itō process
+
+Given two [stochastic processes](/know/concept/stochastic-process/)
+$F_t$ and $G_t$, consider the following random variable $X_t$,
+where $B_t$ is the [Wiener process](/know/concept/wiener-process/),
+i.e. Brownian motion:
+
+$$\begin{aligned}
+ X_t
+ = X_0 + \int_0^t F_s \dd{s} + \int_0^t G_s \dd{B_s}
+\end{aligned}$$
+
+Where the latter is an [Itō integral](/know/concept/ito-integral/),
+assuming $G_t$ is Itō-integrable.
+We call $X_t$ an **Itō process** if $F_t$ is locally integrable,
+and the initial condition $X_0$ is known,
+i.e. $X_0$ is $\mathcal{F}_0$-measurable,
+where $\mathcal{F}_t$ is the filtration
+to which $F_t$, $G_t$ and $B_t$ are adapted.
+The above definition of $X_t$ is often abbreviated as follows,
+where $X_0$ is implicit:
+
+$$\begin{aligned}
+ \dd{X_t}
+ = F_t \dd{t} + G_t \dd{B_t}
+\end{aligned}$$
+
+Typically, $F_t$ is referred to as the **drift** of $X_t$,
+and $G_t$ as its **intensity**.
+Because the Itō integral of $G_t$ is a
+[martingale](/know/concept/martingale/),
+it does not contribute to the mean of $X_t$:
+
+$$\begin{aligned}
+ \mathbf{E}[X_t]
+ = \int_0^t \mathbf{E}[F_s] \dd{s}
+\end{aligned}$$
+
+Now, consider the following **Itō stochastic differential equation** (SDE),
+where $\xi_t = \dv*{B_t}{t}$ is white noise,
+informally treated as the $t$-derivative of $B_t$:
+
+$$\begin{aligned}
+ \dv{X_t}{t}
+ = f(X_t, t) + g(X_t, t) \: \xi_t
+\end{aligned}$$
+
+An Itō process $X_t$ is said to satisfy this equation
+if $f(X_t, t) = F_t$ and $g(X_t, t) = G_t$,
+in which case $X_t$ is also called an **Itō diffusion**.
+All Itō diffusions are [Markov processes](/know/concept/markov-process/),
+since only the current value of $X_t$ determines the future,
+and $B_t$ is also a Markov process.
+
+
+## Itō's lemma
+
+Classically, given $y \equiv h(x(t), t)$,
+the chain rule of differentiation states that:
+
+$$\begin{aligned}
+ \dd{y}
+ = \pdv{h}{t} \dd{t} + \pdv{h}{x} \dd{x}
+\end{aligned}$$
+
+However, for a stochastic process $Y_t \equiv h(X_t, t)$,
+where $X_t$ is an Itō process,
+the chain rule is modified to the following,
+known as **Itō's lemma**:
+
+$$\begin{aligned}
+ \boxed{
+ \dd{Y_t}
+ = \bigg( \pdv{h}{t} + \pdv{h}{x} F_t + \frac{1}{2} \pdv[2]{h}{x} G_t^2 \bigg) \dd{t} + \pdv{h}{x} G_t \dd{B_t}
+ }
+\end{aligned}$$
+
+
+
+
+
+
+We start by applying the classical chain rule,
+but we go to second order in $x$.
+This is also valid classically,
+but there we would neglect all higher-order infinitesimals:
+
+$$\begin{aligned}
+ \dd{Y_t}
+ = \pdv{h}{t} \dd{t} + \pdv{h}{x} \dd{X_t} + \frac{1}{2} \pdv[2]{h}{x} \dd{X_t}^2
+\end{aligned}$$
+
+But here we cannot neglect $\dd{X_t}^2$.
+We insert the definition of an Itō process:
+
+$$\begin{aligned}
+ \dd{Y_t}
+ &= \pdv{h}{t} \dd{t} + \pdv{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big) + \frac{1}{2} \pdv[2]{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big)^2
+ \\
+ &= \pdv{h}{t} \dd{t} + \pdv{h}{x} \Big( F_t \dd{t} + G_t \dd{B_t} \Big)
+ + \frac{1}{2} \pdv[2]{h}{x} \Big( F_t^2 \dd{t}^2 + 2 F_t G_t \dd{t} \dd{B_t} + G_t^2 \dd{B_t}^2 \Big)
+\end{aligned}$$
+
+In the limit of small $\dd{t}$, we can neglect $\dd{t}^2$,
+and as it turns out, $\dd{t} \dd{B_t}$ too:
+
+$$\begin{aligned}
+ \dd{t} \dd{B_t}
+ &= (B_{t + \dd{t}} - B_t) \dd{t}
+ \sim \dd{t} \mathcal{N}(0, \dd{t})
+ \sim \mathcal{N}(0, \dd{t}^3)
+ \longrightarrow 0
+\end{aligned}$$
+
+However, due to the scaling property of $B_t$,
+we cannot ignore $\dd{B_t}^2$, which has order $\dd{t}$:
+
+$$\begin{aligned}
+ \dd{B_t}^2
+ &= (B_{t + \dd{t}} - B_t)^2
+ \sim \big( \mathcal{N}(0, \dd{t}) \big)^2
+ \sim \chi^2_1(\dd{t})
+ \longrightarrow \dd{t}
+\end{aligned}$$
+
+Where $\chi_1^2(\dd{t})$ is the generalized chi-squared distribution
+with one term of variance $\dd{t}$.
+
+
+
+The most important application of Itō's lemma
+is to perform coordinate transformations,
+to make the solution of a given Itō SDE easier.
+
+
+## Coordinate transformations
+
+The simplest coordinate transformation is a scaling of the time axis.
+Defining $s \equiv \alpha t$, the goal is to keep the Itō process.
+We know how to scale $B_t$, be setting $W_s \equiv \sqrt{\alpha} B_{s / \alpha}$.
+Let $Y_s \equiv X_t$ be the new variable on the rescaled axis, then:
+
+$$\begin{aligned}
+ \dd{Y_s}
+ = \dd{X_t}
+ &= f(X_t) \dd{t} + g(X_t) \dd{B_t}
+ \\
+ &= \frac{1}{\alpha} f(Y_s) \dd{s} + \frac{1}{\sqrt{\alpha}} g(Y_s) \dd{W_s}
+\end{aligned}$$
+
+$W_s$ is a valid Wiener process,
+and the other changes are small,
+so this is still an Itō process.
+
+To solve SDEs analytically, it is usually best
+to have additive noise, i.e. $g = 1$.
+This can be achieved using the **Lamperti transform**:
+define $Y_t \equiv h(X_t)$, where $h$ is given by:
+
+$$\begin{aligned}
+ \boxed{
+ h(x)
+ = \int_{x_0}^x \frac{1}{g(y)} \dd{y}
+ }
+\end{aligned}$$
+
+Then, using Itō's lemma, it is straightforward
+to show that the intensity becomes $1$.
+Note that the lower integration limit $x_0$ does not enter:
+
+$$\begin{aligned}
+ \dd{Y_t}
+ &= \bigg( f(X_t) \: h'(X_t) + \frac{1}{2} g^2(X_t) \: h''(X_t) \bigg) \dd{t} + g(X_t) \: h'(X_t) \dd{B_t}
+ \\
+ &= \bigg( \frac{f(X_t)}{g(X_t)} - \frac{1}{2} g^2(X_t) \frac{g'(X_t)}{g^2(X_t)} \bigg) \dd{t} + \frac{g(X_t)}{g(X_t)} \dd{B_t}
+ \\
+ &= \bigg( \frac{f(X_t)}{g(X_t)} - \frac{1}{2} g'(X_t) \bigg) \dd{t} + \dd{B_t}
+\end{aligned}$$
+
+Similarly, we can eliminate the drift $f = 0$,
+thereby making the Itō process a martingale.
+This is done by defining $Y_t \equiv h(X_t)$, with $h(x)$ given by:
+
+$$\begin{aligned}
+ \boxed{
+ h(x)
+ = \int_{x_0}^x \exp\!\bigg( \!-\!\! \int_{x_1}^y \frac{2 f(z)}{g^2(z)} \dd{z} \bigg) \dd{y}
+ }
+\end{aligned}$$
+
+The goal is to make the parenthesized first term (see above)
+of Itō's lemma disappear, which this $h(x)$ does indeed do.
+Note that $x_0$ and $x_1$ do not enter:
+
+$$\begin{aligned}
+ 0
+ &= f(x) \: h'(x) + \frac{1}{2} g^2(x) \: h''(x)
+ \\
+ &= \Big( f(x) - \frac{1}{2} g^2(x) \frac{2 f(x)}{g^2(x)} \Big) \exp\!\bigg( \!-\!\! \int_{x_1}^x \frac{2 f(y)}{g^2(y)} \dd{y} \bigg)
+\end{aligned}$$
+
+
+## Existence and uniqueness
+
+It is worth knowing under what condition a solution to a given SDE exists,
+in the sense that it is finite on the entire time axis.
+Suppose the drift $f$ and intensity $g$ satisfy these inequalities,
+for some known constant $K$ and for all $x$:
+
+$$\begin{aligned}
+ x f(x) \le K (1 + x^2)
+ \qquad \quad
+ g^2(x) \le K (1 + x^2)
+\end{aligned}$$
+
+When this is satisfied, we can find the following upper bound
+on an Itō process $X_t$,
+which clearly implies that $X_t$ is finite for all $t$:
+
+$$\begin{aligned}
+ \boxed{
+ \mathbf{E}[X_t^2]
+ \le \big(X_0^2 + 3 K t\big) \exp\!\big(3 K t\big)
+ }
+\end{aligned}$$
+
+
+
+
+
+
+If we define $Y_t \equiv X_t^2$,
+then Itō's lemma tells us that the following holds:
+
+$$\begin{aligned}
+ \dd{Y_t}
+ = \big( 2 X_t \: f(X_t) + g^2(X_t) \big) \dd{t} + 2 X_t \: g(X_t) \dd{B_t}
+\end{aligned}$$
+
+Integrating and taking the expectation value
+removes the Wiener term, leaving:
+
+$$\begin{aligned}
+ \mathbf{E}[Y_t]
+ = Y_0 + \mathbf{E}\! \int_0^t 2 X_s f(X_s) + g^2(X_s) \dd{s}
+\end{aligned}$$
+
+Given that $K (1 \!+\! x^2)$ is an upper bound of $x f(x)$ and $g^2(x)$,
+we get an inequality:
+
+$$\begin{aligned}
+ \mathbf{E}[Y_t]
+ &\le Y_0 + \mathbf{E}\! \int_0^t 2 K (1 \!+\! X_s^2) + K (1 \!+\! X_s^2) \dd{s}
+ \\
+ &\le Y_0 + \int_0^t 3 K (1 + \mathbf{E}[Y_s]) \dd{s}
+ \\
+ &\le Y_0 + 3 K t + \int_0^t 3 K \big( \mathbf{E}[Y_s] \big) \dd{s}
+\end{aligned}$$
+
+We then apply the
+[Grönwall-Bellman inequality](/know/concept/gronwall-bellman-inequality/),
+noting that $(Y_0 \!+\! 3 K t)$ does not decrease with time, leading us to:
+
+$$\begin{aligned}
+ \mathbf{E}[Y_t]
+ &\le (Y_0 + 3 K t) \exp\!\bigg( \int_0^t 3 K \dd{s} \bigg)
+ \\
+ &\le (Y_0 + 3 K t) \exp\!\big(3 K t\big)
+\end{aligned}$$
+
+
+
+If a solution exists, it is also worth knowing whether it is unique.
+Suppose that $f$ and $g$ satisfy the following inequalities,
+for some constant $K$ and for all $x$ and $y$:
+
+$$\begin{aligned}
+ \big| f(x) - f(y) \big| \le K \big| x - y \big|
+ \qquad \quad
+ \big| g(x) - g(y) \big| \le K \big| x - y \big|
+\end{aligned}$$
+
+Let $X_t$ and $Y_t$ both be solutions to a given SDE,
+but the initial conditions need not be the same,
+such that the difference is initially $X_0 \!-\! Y_0$.
+Then the difference $X_t \!-\! Y_t$ is bounded by:
+
+$$\begin{aligned}
+ \boxed{
+ \mathbf{E}\big[ (X_t - Y_t)^2 \big]
+ \le (X_0 - Y_0)^2 \exp\!\Big( \big(2 K \!+\! K^2 \big) t \Big)
+ }
+\end{aligned}$$
+
+
+
+
+
+
+We define $D_t \equiv X_t \!-\! Y_t$ and $Z_t \equiv D_t^2 \ge 0$,
+together with $F_t \equiv f(X_t) \!-\! f(Y_t)$ and $G_t \equiv g(X_t) \!-\! g(Y_t)$,
+such that Itō's lemma states:
+
+$$\begin{aligned}
+ \dd{Z_t}
+ = \big( 2 D_t F_t + G_t^2 \big) \dd{t} + 2 D_t G_t \dd{B_t}
+\end{aligned}$$
+
+Integrating and taking the expectation value
+removes the Wiener term, leaving:
+
+$$\begin{aligned}
+ \mathbf{E}[Z_t]
+ = Z_0 + \mathbf{E}\! \int_0^t 2 D_s F_s + G_s^2 \dd{s}
+\end{aligned}$$
+
+The *Cauchy-Schwarz inequality* states that $|D_s F_s| \le |D_s| |F_s|$,
+and then the given fact that $F_s$ and $G_s$ satisfy
+$|F_s| \le K |D_s|$ and $|G_s| \le K |D_s|$ gives:
+
+$$\begin{aligned}
+ \mathbf{E}[Z_t]
+ &\le Z_0 + \mathbf{E}\! \int_0^t 2 K D_s^2 + K^2 D_s^2 \dd{s}
+ \\
+ &\le Z_0 + \int_0^t (2 K \!+\! K^2) \: \mathbf{E}[Z_s] \dd{s}
+\end{aligned}$$
+
+Where we have implicitly used that $D_s F_s = |D_s F_s|$
+because $Z_t$ is positive for all $G_s^2$,
+and that $|D_s|^2 = D_s^2$ because $D_s$ is real.
+We then apply the
+[Grönwall-Bellman inequality](/know/concept/gronwall-bellman-inequality/),
+recognizing that $Z_0$ does not decrease with time (since it is constant):
+
+$$\begin{aligned}
+ \mathbf{E}[Z_t]
+ &\le Z_0 \exp\!\bigg( \int_0^t 2 K \!+\! K^2 \dd{s} \bigg)
+ \\
+ &\le Z_0 \exp\!\Big( \big( 2 K \!+\! K^2 \big) t \Big)
+\end{aligned}$$
+
+
+
+Using these properties, it can then be shown
+that if all of the above conditions are satisfied,
+then the SDE has a unique solution,
+which is $\mathcal{F}_t$-adapted, continuous, and exists for all times.
+
+
+
+## References
+1. U.H. Thygesen,
+ *Lecture notes on diffusions and stochastic differential equations*,
+ 2021, Polyteknisk Kompendie.
diff --git a/content/know/concept/langmuir-waves/index.pdc b/content/know/concept/langmuir-waves/index.pdc
index cd9b449..3c3f1d2 100644
--- a/content/know/concept/langmuir-waves/index.pdc
+++ b/content/know/concept/langmuir-waves/index.pdc
@@ -34,7 +34,7 @@ We also need [Gauss' law](/know/concept/maxwells-equations/):
$$\begin{aligned}
\varepsilon_0 \nabla \cdot \vb{E}
- = q_e (n_i - n_e)
+ = q_e (n_e - n_i)
\end{aligned}$$
We split $n_e$, $\vb{u}_e$ and $\vb{E}$ into a base component
@@ -85,10 +85,10 @@ and use the plasma's quasi-neutrality $n_i = n_{e0}$ to get:
$$\begin{aligned}
\varepsilon_0 \nabla \cdot \big( \vb{E}_0 \!+\! \vb{E}_1 \big)
- = q_e (n_i - n_{e0} \!-\! n_{e1} )
+ = q_e (n_{e0} + n_{e1} - n_i)
\quad \implies \quad
\varepsilon_0 \nabla \cdot \vb{E}_1
- = - q_e n_{e1}
+ = q_e n_{e1}
\end{aligned}$$
Since we are looking for linear waves,
@@ -110,7 +110,7 @@ Inserting this into the continuity equation and Gauss' law yields, respectively:
$$\begin{aligned}
- i \omega n_{e1} = - i n_{e0} \vb{k} \cdot \vb{u}_{e1}
\qquad \quad
- i \varepsilon_0 \vb{k} \cdot \vb{E}_1 = q_e n_{e1}
+ -\! i \varepsilon_0 \vb{k} \cdot \vb{E}_1 = q_e n_{e1}
\end{aligned}$$
However, there are three unknowns $n_{e1}$, $\vb{u}_{e1}$ and $\vb{E}_1$,
diff --git a/content/know/concept/magnetohydrodynamics/index.pdc b/content/know/concept/magnetohydrodynamics/index.pdc
index 6672a74..89d23db 100644
--- a/content/know/concept/magnetohydrodynamics/index.pdc
+++ b/content/know/concept/magnetohydrodynamics/index.pdc
@@ -333,7 +333,7 @@ This term can be dropped in any of the following cases:
$$\begin{gathered}
1
- \gg \frac{\big| \vb{J} \cross \vb{B} / q_e n_e \big|}{\big| \vb{U} \cross \vb{B} \big|}
+ \gg \frac{\big| \vb{J} \cross \vb{B} / q_e n_e \big|}{\big| \vb{u} \cross \vb{B} \big|}
\sim \frac{\rho v_\mathrm{char} / \tau_\mathrm{char}}{v_\mathrm{char} |\vb{B}| q_i n_i}
\approx \frac{m_i n_i}{|\vb{B}| q_i n_i \tau_\mathrm{char}}
= \frac{1}{\omega_{ci} \tau_\mathrm{char}}
@@ -366,7 +366,7 @@ where we have used Ampère's law to find $\vb{J} \sim \vb{B} / \mu_0 \lambda_\ma
$$\begin{aligned}
1
- \ll \frac{\big| \vb{U} \cross \vb{B} \big|}{\big| \eta \vb{J} \big|}
+ \ll \frac{\big| \vb{u} \cross \vb{B} \big|}{\big| \eta \vb{J} \big|}
\sim \frac{v_\mathrm{char} |\vb{B}|}{\eta \vb{J}}
\sim \frac{v_\mathrm{char} |\vb{B}|}{\eta |\vb{B}| / \mu_0 \lambda_\mathrm{char}}
= \mathrm{R_m}
diff --git a/content/know/concept/time-dependent-perturbation-theory/index.pdc b/content/know/concept/time-dependent-perturbation-theory/index.pdc
index 1fbd9ce..76ab684 100644
--- a/content/know/concept/time-dependent-perturbation-theory/index.pdc
+++ b/content/know/concept/time-dependent-perturbation-theory/index.pdc
@@ -59,13 +59,13 @@ We then take the inner product with an arbitrary stationary basis state $\ket{m}
$$\begin{aligned}
0
- &= \sum_{n} \Big( \lambda c_n \matrixel{m}{\hat{H}_1}{n} - i \hbar \frac{d c_n}{dt} \braket{m}{n} \Big) \exp\!(- i E_n t / \hbar)
+ &= \sum_{n} \Big( \lambda c_n \matrixel{m}{\hat{H}_1}{n} - i \hbar \dv{c_n}{t} \braket{m}{n} \Big) \exp\!(- i E_n t / \hbar)
\end{aligned}$$
Thanks to orthonormality, this removes the latter term from the summation:
$$\begin{aligned}
- i \hbar \frac{d c_m}{dt} \exp\!(- i E_m t / \hbar)
+ i \hbar \dv{c_m}{t} \exp\!(- i E_m t / \hbar)
&= \lambda \sum_{n} c_n \matrixel{m}{\hat{H}_1}{n} \exp\!(- i E_n t / \hbar)
\end{aligned}$$
@@ -74,7 +74,7 @@ $\omega_{mn} \equiv (E_m - E_n) / \hbar$ to get:
$$\begin{aligned}
\boxed{
- i \hbar \frac{d c_m}{dt}
+ i \hbar \dv{c_m}{t}
= \lambda \sum_{n} c_n(t) \matrixel{m}{\hat{H}_1(t)}{n} \exp\!(i \omega_{mn} t)
}
\end{aligned}$$
--
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