--- title: "Guiding center theory" firstLetter: "G" publishDate: 2021-09-21 categories: - Physics - Electromagnetism - Plasma physics date: 2021-09-18T13:47:41+02:00 draft: false markup: pandoc --- # Guiding center theory When discussing the [Lorentz force](/know/concept/lorentz-force/), we introduced the concept of *gyration*: a particle in a uniform [magnetic field](/know/concept/magnetic-field/) $\vb{B}$ *gyrates* in a circular orbit around a **guiding center**. Here, we will generalize this result to more complicated situations, for example involving [electric fields](/know/concept/electric-field/). The particle's equation of motion combines the Lorentz force $\vb{F}$ with Newton's second law: $$\begin{aligned} \vb{F} = m \dv{\vb{u}}{t} = q \big( \vb{E} + \vb{u} \cross \vb{B} \big) \end{aligned}$$ We now allow the fields vary slowly in time and space. We thus add deviations $\delta\vb{E}$ and $\delta\vb{B}$: $$\begin{aligned} \vb{E} \to \vb{E} + \delta\vb{E}(\vb{x}, t) \qquad \quad \vb{B} \to \vb{B} + \delta\vb{B}(\vb{x}, t) \end{aligned}$$ Meanwhile, the velocity $\vb{u}$ can be split into the guiding center's motion $\vb{u}_{gc}$ and the *known* Larmor gyration $\vb{u}_L$ around the guiding center, such that $\vb{u} = \vb{u}_{gc} + \vb{u}_L$. Inserting: $$\begin{aligned} m \dv{t} \big( \vb{u}_{gc} + \vb{u}_L \big) = q \big( \vb{E} + \delta\vb{E} + (\vb{u}_{gc} + \vb{u}_L) \cross (\vb{B} + \delta\vb{B}) \big) \end{aligned}$$ We already know that $m \: \dv*{\vb{u}_L}{t} = q \vb{u}_L \cross \vb{B}$, which we subtract from the total to get: $$\begin{aligned} m \dv{\vb{u}_{gc}}{t} = q \big( \vb{E} + \delta\vb{E} + \vb{u}_{gc} \cross (\vb{B} + \delta\vb{B}) + \vb{u}_L \cross \delta\vb{B} \big) \end{aligned}$$ This will be our starting point. Before proceeding, we also define the average of $\expval{f}$ of a function $f$ over a single gyroperiod, where $\omega_c$ is the cyclotron frequency: $$\begin{aligned} \expval{f} \equiv \int_0^{2 \pi / \omega_c} f(t) \dd{t} \end{aligned}$$ Assuming that gyration is much faster than the guiding center's motion, we can use this average to approximately remove the finer dynamics, and focus only on the guiding center. ## Uniform electric and magnetic field Consider the case where $\vb{E}$ and $\vb{B}$ are both uniform, such that $\delta\vb{B} = 0$ and $\delta\vb{E} = 0$: $$\begin{aligned} m \dv{\vb{u}_{gc}}{t} = q \big( \vb{E} + \vb{u}_{gc} \cross \vb{B} \big) \end{aligned}$$ Dotting this with the unit vector $\vu{b} \equiv \vb{B} / |\vb{B}|$ makes all components perpendicular to $\vb{B}$ vanish, including the cross product, leaving only the (scalar) parallel components $u_{gc\parallel}$ and $E_\parallel$: $$\begin{aligned} m \dv{u_{gc\parallel}}{t} = \frac{q}{m} E_{\parallel} \end{aligned}$$ This simply describes a constant acceleration, and is easy to integrate. Next, the equation for $\vb{u}_{gc\perp}$ is found by subtracting $u_{gc\parallel}$'s equation from the original: $$\begin{aligned} m \dv{\vb{u}_{gc\perp}}{t} = q (\vb{E} + \vb{u}_{gc} \cross \vb{B}) - q E_\parallel \vu{b} = q (\vb{E}_\perp + \vb{u}_{gc\perp} \cross \vb{B}) \end{aligned}$$ Keep in mind that $\vb{u}_{gc\perp}$ explicitly excludes gyration. If we try to split $\vb{u}_{gc\perp}$ into a constant and a time-dependent part, and choose the most convenient constant, we notice that the only way to exclude gyration is to demand that $\vb{u}_{gc\perp}$ does not depend on time. Therefore: $$\begin{aligned} 0 = \vb{E}_\perp + \vb{u}_{gc\perp} \cross \vb{B} \end{aligned}$$ To find $\vb{u}_{gc\perp}$, we take the cross product with $\vb{B}$, and use the fact that $\vb{B} \cross \vb{E}_\perp = \vb{B} \cross \vb{E}$: $$\begin{aligned} 0 = \vb{B} \cross (\vb{E}_\perp + \vb{u}_{gc\perp} \cross \vb{B}) = \vb{B} \cross \vb{E} + \vb{u}_{gc\perp} B^2 \end{aligned}$$ Rearranging this shows that $\vb{u}_{gc\perp}$ is constant. The guiding center drifts sideways at this speed, hence it is called a **drift velocity** $\vb{v}_E$. Curiously, $\vb{v}_E$ is independent of $q$: $$\begin{aligned} \boxed{ \vb{v}_E = \frac{\vb{E} \cross \vb{B}}{B^2} } \end{aligned}$$ Drift is not specific to an electric field: $\vb{E}$ can be replaced by a general force $\vb{F}/q$ without issues. In that case, the resulting drift velocity $\vb{v}_F$ does depend on $q$: $$\begin{aligned} \boxed{ \vb{v}_F = \frac{\vb{F} \cross \vb{B}}{q B^2} } \end{aligned}$$ ## Non-uniform magnetic field Next, consider a more general case, where $\vb{B}$ is non-uniform, but $\vb{E}$ is still uniform: $$\begin{aligned} m \dv{\vb{u}_{gc}}{t} = q \big( \vb{E} + \vb{u}_{gc} \cross (\vb{B} + \delta\vb{B}) + \vb{u}_L \cross \delta\vb{B} \big) \end{aligned}$$ Assuming the gyroradius $r_L$ is small compared to the variation of $\vb{B}$, we set $\delta\vb{B}$ to the first-order term of a Taylor expansion of $\vb{B}$ around $\vb{x}_{gc}$, that is, $\delta\vb{B} = (\vb{x}_L \cdot \nabla) \vb{B}$. We thus have: $$\begin{aligned} m \dv{\vb{u}_{gc}}{t} = q \big( \vb{E} + \vb{u}_{gc} \cross \vb{B} + \vb{u}_{gc} \cross (\vb{x}_L \cdot \nabla) \vb{B} + \vb{u}_L \cross (\vb{x}_L \cdot \nabla) \vb{B} \big) \end{aligned}$$ We approximate this by taking the average over a single gyration, as defined earlier: $$\begin{aligned} m \dv{\vb{u}_{gc}}{t} = q \big( \vb{E} + \vb{u}_{gc} \cross \vb{B} + \vb{u}_{gc} \cross \expval{ (\vb{x}_L \cdot \nabla) \vb{B} } + \expval{ \vb{u}_L \cross (\vb{x}_L \cdot \nabla) \vb{B} } \big) \end{aligned}$$ Where we have used that $\expval{\vb{u}_{gc}} = \vb{u}_{gc}$. The two averaged expressions turn out to be: $$\begin{aligned} \expval{ (\vb{x}_L \cdot \nabla) \vb{B} } = 0 \qquad \quad \expval{ \vb{u}_L \cross (\vb{x}_L \cdot \nabla) \vb{B} } \approx - \frac{u_L^2}{2 \omega_c} \nabla B \end{aligned}$$