Impact of Coulomb Scattering on Argon Plasma Based Thermionic Converter Performance

TL;DR

This study uses advanced PIC simulations to reassess how Coulomb scattering affects argon plasma thermionic converters, finding that previous models overestimated its negative impact and providing new insights into device performance.

Contribution

The paper introduces a fully kinetic PIC simulation approach to evaluate Coulomb collision effects, challenging earlier simplified models and refining understanding of plasma resistance in thermionic converters.

Findings

Coulomb collisions have a less severe impact than previously thought.

Earlier models overestimated the negative effects of Coulomb scattering.

Simulation results provide insights into the validity of simplified assumptions.

Abstract

Particle-in-cell (PIC) simulations were performed to study the impact of Coulomb scattering on the performance of argon plasma based thermionic converters. Using a simplified model, studies from the 1970's have concluded that plasma resistance, brought on by Coulomb collisions, causes a shift in the IV-curves of thermionic converters that use an argon plasma to mitigate space charge, thereby strongly limiting their electricity generation capability. In this work the impact of Coulomb collisions in such devices were studied as a function of the relative electrical potential between the electrodes, with higher fidelity through the use of a fully kinetic approach (PIC). This revealed that earlier reports overestimated the negative impact of Coulomb collisions around the flat-band potential. The results of the simulations are also used to comment on the validity of the assumptions made in the simplified model.