Spatially resolved laser Thomson scattering measurements in a negative glow and cathode presheath to investigate a 1D sheath model

Abstract

This paper presents spatially resolved laser Thomson scattering measurements in a cathode presheath and describes a new approximation for the electric field at the plasma-sheath boundary that accounts for collisional and ionization effects. The approximation is derived from a 1D sheath model using asymptotic theory, and the approximation is validated against the exact solution of the 1D model. The approximation of the electric field at the plasma-sheath boundary is examined with experimentally measured profiles of electron properties in the cathode presheath and negative glow of a glow discharge. The measurements are made with a noninvasive laser Thomson scattering system applied to a 20 kV pulsed plasma with an electrode gap of 26.53 mm at neutral pressures of 2, 2.5, and 25 Torr for argon, krypton, and helium, respectively. Peak electron densities for the He, Ar, and Kr plasmas are around 9 × 1018, 2.4 × 1019, and 7.5 × 1019 m−3, respectively. For all the gases, the electrons in the negative glow are approximately isothermal at electron temperatures between 1 and 2 eV, and for He and Ar, the electrons were not isothermal in the cathode presheath. The electron density profile in the cathode presheath was nonmonotonic, and calculations of the ionization rate indicate that a sharp increase in the ionization rate may produce a nonmonotonic density profile in the cathode presheath. The insights gained from spatially-resolved noninvasive measurements of electron properties in a cathode sheath reveal the need for more detailed cathode sheath models.