Development of xenon collisional radiative model for plasma diagnostics of Hall Effect thrusters

Authors

DOI:

https://doi.org/10.15587/1729-4061.2017.96649

Keywords:

collisional radiative model, Hall effect thruster, optical emission spectroscopy, plasma, electron temperature

Abstract

Hall Effect thrusters (HET) have demonstrated its applicability on satellites for the Low earth orbit (LEO), Geo-stationary earth orbit (GEO) and long duration missions. High thrust density and long lifetimes are attractive parameters of the HET. In order to improve the thruster performance and lifetimes, decades of efforts are made to understand the plasma physics.

Several intrusive and non-intrusive diagnostics techniques are employed for HET investigation. Simple and precise diagnostics technique is attractive to delineate the characteristics of the thruster. Optical emission spectroscopy provides several advantages over the other methods which are used for the HET diagnostics. Using this diagnostics tool in correlation with the collisional radiative model, the information of electron kinetics is extracted instantaneously.

Collisional radiative model is developed by using the xenon near-infrared emission lines. This kinetic model can be used to determine the local electron temperature with error less than 15 % for investigating the HET physics.

Author Biographies

Rajendrasing Rajput, National Aerospace University named after M. Zhukovsky Kharkiv Aviation Institute Chkalova str., 17, Kharkiv, Ukraine, 61070

Department of Electric Propulsion Thrusters

Aloyna Khaustova, National Aerospace University named after M. Zhukovsky Kharkiv Aviation Institute Chkalova str., 17, Kharkiv, Ukraine, 61070

Postgraduate Student

Department of Electric Propulsion Thrusters

Andriy Loyan, National Aerospace University named after M. Zhukovsky Kharkiv Aviation Institute Chkalova str., 17, Kharkiv, Ukraine, 61070

Senior Researcher

Department of Electric Propulsion Thrusters

References

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Published

2017-04-29

How to Cite

Rajput, R., Khaustova, A., & Loyan, A. (2017). Development of xenon collisional radiative model for plasma diagnostics of Hall Effect thrusters. Eastern-European Journal of Enterprise Technologies, 2(8 (86), 24–29. https://doi.org/10.15587/1729-4061.2017.96649

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Section

Energy-saving technologies and equipment