Large gyro-orbit model of ion velocity distribution in plasma near a wall in a grazing-angle magnetic field

Abstract

A model is presented for the ion distribution function in a plasma at a solid target with a magnetic field B inclined at a small angle, α 1 (in radians), to the target. Adiabatic electrons are assumed, requiring αZm e/m i where m e and m i are the electron and ion mass respectively, and Z is the charge state of the ion. An electric field E is present to repel electrons, and so the characteristic size of the electrostatic potential φ is set by the electron temperature T e, eφ T e, where e is the proton charge. An asymptotic scale separation between the Debye length, λ D=ε0 Te/e2 ne, the ion sound gyroradius s= m i(ZT e+T i)/(ZeB), and the size of the collisional region d c = α λ mfp is assumed, λ D s d c. Here ε0 is the permittivity of free space, n e is the electron density, T i is the ion temperature, B= |B| and λ mfp is the collisional mean free path of an ion. The form of the ion distribution function is assumed at distances x from the wall such that s x d c. A self-consistent solution of φ (x) is required to solve for the ion trajectories and for the ion distribution function at the target. The model presented here allows to bypass the numerical solution of φ (x) and results in an analytical expression for the ion distribution function at the target. It assumes that τ=T i/(ZT e) 1, and ignores the electric force on the ion trajectory until close to the target. For τ 1, the model provides a fast approximation to energy-angle distributions of ions at the target. These can be used to make sputtering predictions.