Establishing Criteria for the Transition from Kinetic to Fluid Modeling in Hollow Cathode Analysis

Abstract: In this study, we conduct 2D3V Particle-In-Cell simulations of hollow cathodes, encompassing both the channel and plume region, with an emphasis on plasma switch applications. The plasma in the hollow cathode channel can exhibit kinetic effects depending on how fast electrons emitted from the insert are thermalized via Coulomb collisions. The criterion that determines whether the plasma operates in a Duid or kinetic regime is given as follows. When Coulomb collisions occur at a much greater rate than ionization or excitation events, the Electron Energy Distribution Function relaxes to aMaxwellian distribution and the plasmawithin the channel can be describedwith aDuidmodel. In contrast, if inelastic processes are much faster, then the Electron Energy Distribution Function in the channel exhibits a notable high-energy tail, and a kinetic treatment is required. This criterion is applied to other kinds of hollow cathodes from the literature, revealing that a Duid approach is suitable for most electric propulsion applications, whereas a kinetic treatment might be necessary for plasma switches. Additionally, amomentumbalance reveals that a diffusion equation is sufAcient to predict the plasma plume expansion, a crucial input in the design of hollow cathodes for plasma switch applications.