--- title: "Boltzmann relation" firstLetter: "B" publishDate: 2021-10-18 categories: - Physics - Plasma physics date: 2021-10-18T15:25:39+02:00 draft: false markup: pandoc --- # Boltzmann relation In a plasma where the ions and electrons are both in thermal equilibrium, and in the absence of short-lived induced electromagnetic fields, their densities $n_i$ and $n_e$ can be predicted. By definition, a particle in an [electric field](/know/concept/electric-field/) $\vb{E}$ experiences a [Lorentz force](/know/concept/lorentz-force/) $\vb{F}_e$. This corresponds to a force density $\vb{f}_e$, such that $\vb{F}_e = \vb{f}_e \dd{V}$. For the electrons, we thus have: $$\begin{aligned} \vb{f}_e = q_e n_e \vb{E} = - q_e n_e \nabla \phi \end{aligned}$$ Meanwhile, if we treat the electrons as a gas obeying the ideal gas law $p_e = k_B T_e n_e$, then the pressure $p_e$ leads to another force density $\vb{f}_p$: $$\begin{aligned} \vb{f}_p = - \nabla p_e = - k_B T_e \nabla n_e \end{aligned}$$ At equilibrium, we demand that $\vb{f}_e = \vb{f}_p$, and isolate this equation for $\nabla n_e$, yielding: $$\begin{aligned} k_B T_e \nabla n_e = q_e n_e \nabla \phi \quad \implies \quad \nabla n_e = \frac{q_e \nabla \phi}{k_B T_e} n_e = \nabla \bigg( \frac{q_e \phi}{k_B T_e} \bigg) n_e \end{aligned}$$ This equation is straightforward to integrate, leading to the following expression for $n_e$, known as the **Boltzmann relation**, due to its resemblance to the statistical Boltzmann distribution (see [canonical ensemble](/know/concept/canonical-ensemble/)): $$\begin{aligned} \boxed{ n_e(\vb{r}) = n_{e0} \exp\!\bigg( \!-\! \frac{q_e \phi(\vb{r})}{k_B T_e} \bigg) } \end{aligned}$$ Where the linearity factor $n_{e0}$ represents the electron density for $\phi = 0$. We can do the same for ions instead of electrons, leading to the following ion density $n_i$: $$\begin{aligned} \boxed{ n_i(\vb{r}) = n_{i0} \exp\!\bigg( \!-\! \frac{q_i \phi(\vb{r})}{k_B T_i} \bigg) } \end{aligned}$$ However, due to their larger mass, ions are much slower to respond to fluctuations in the above equilibrium. Consequently, after a perturbation, the ions spend much more time in a transient non-equilibrium state than the electrons, so this formula for $n_i$ is only valid if the perturbation is sufficiently slow, allowing the ions to keep up. Usually, electrons do not suffer the same issue, thanks to their small mass and fast response. ## References 1. P.M. Bellan, *Fundamentals of plasma physics*, 1st edition, Cambridge. 2. M. Salewski, A.H. Nielsen, *Plasma physics: lecture notes*, 2021, unpublished.