A model for plasma-neutral fluid interaction and its application to a study of CT formation in a magnetised Marshall gun

TL;DR

The paper develops a plasma-neutral fluid interaction model integrated into the DELiTE framework, applied to study CT formation in magnetized Marshall guns, revealing mechanisms behind electron density increases and temperature changes.

Contribution

A novel plasma-neutral interaction model including energy transfer rates was developed and applied to magnetized gun experiments, clarifying CT formation mechanisms.

Findings

Neutral gas diffusion leads to increased electron density after CT formation.

Edge biasing affects temperature and density by creating a transport barrier.

Model explains observed plasma behavior in SPECTOR experiments.

Abstract

A model for plasma/neutral fluid interaction was developed and included in the DELiTE code framework implementation of non-linear MHD equations. The source rates of ion, electron and neutral fluid momentum and energy due to ionization and recombination are derived using a simple method that enables determination of the volumetric rate of thermal energy transfer from electrons to photons and neutral particles in the radiative recombination reaction. This quantity can not be evaluated with the standard formal procedure of taking moments of the relevant collision operator, and has been neglected in other studies. The plasma/neutral fluid interaction model was applied to study CT formation in the SMRT and SPECTOR magnetized Marshall guns, enabling clarification of the mechanisms behind the significant increases in CT electron density that are routinely observed well after formation on the SPECTOR experiment. Neutral gas, which remains concentrated below the gas valves after CT formation, diffuses up the gun barrel to the CT containment region where it is ionized, leading to the observed electron density increases. This understanding helps account for the exceptionally significant increase in temperature, and markedly reduced density, observed during the electrode edge biasing experiment conducted on SPECTOR. It is thought that edge fueling impediment, a consequence of a biasing-induced transport barrier, is largely responsible for the observed temperature increase and density decrease.