The IPG6-B as a Research Facility to support Future Development of Electric Propulsion

TL;DR

The IPG6-B plasma generator at Baylor University is a versatile research tool characterized for various plasma applications, supporting future electric propulsion development and fundamental plasma research.

Contribution

This paper details the characterization of the IPG6-B facility, including flow conditions, power efficiency, and plasma parameters, establishing it as a reliable platform for diverse plasma studies.

Findings

Flow conditions characterized for multiple gases and Mach numbers.

Power coupling efficiency varies with gas type and pressure.

Electron temperatures and densities measured, enabling advanced plasma research.

Abstract

The inductively-heated plasma generator IPG6-B at Baylor University has been established and characterized in previous years for use as a flexible experimental research facility across multiple applications. The system uses a similar plasma generator design to its twin-facilities at the University of Stuttgart (IPG6-S) and the University of Kentucky (IPG6-UKY). The similarity between these three devices offers the advantage to reproduce results and provides comparability to achieve cross-referencing and verification. Sub- and supersonic flow conditions for Mach numbers between $Ma = 0.3 - 1.4$ have been characterized for air, argon, helium and nitrogen using a pitot probe. Overall power coupling efficiency as well as specific bulk enthalpy of the flow have been determined by calorimeter measurements to be between $\eta = 0.05 - 0.45$ and $h_s = 5- 35$ MJ/kg respectively depending on gas type and pressure. Electron temperatures of $T_e = 1 - 2$ eV and densities $n_e = 10^{18} - 10^{20} m^{-3}$ have been measured using an electrostatic probe system. At Baylor University, laboratory experiments in the areas of astrophysics, geophysics as well as fundamental research on complex (dusty) plasmas are planned. Most recent experiments include the study of dusty plasmas and astrophysical phenomena and the interaction of charged dust with electric and magnetic fields. In this case, dust can be used as a diagnostic for such fields and can reveal essential information of the magneto-hydrodynamics in low-temperature plasmas.