Direct current arc plasma thrusters for space applications: basic physics, design and perspectives

O. Baranov; I. Levchenko; S. Xu; X. G. Wang; H. P. Zhou; K. Bazaka

doi:10.1007/s41614-019-0023-3

Direct current arc plasma thrusters for space applications: basic physics, design and perspectives

O. Baranov^*, I. Levchenko^*, S. Xu, X. G. Wang, H. P. Zhou, K. Bazaka^*

^*Corresponding author for this work

Research output: Contribution to journal › Review article › peer-review

21 Citations (Scopus)

Abstract

Renewed interest in space exploration and aspirations for colonization of Mars, Moon and possibly other extra-terrestrial bodies puts pressure on the present-day space technology to become more efficient. Space engines, or thrusters, are the key element of any spacecraft and thus, continuous improvement in thruster design and performance is needed to realize the mankind’s goal of becoming a truly space faring civilization. Space micropropulsion systems that utilize plasma and electric fields to accelerate and expel mass to produce reactive thrust are advanced propulsion systems that can deliver very high specific impulse. In this review, we outline basic physical principles and design approaches for future direct-arc plasma propulsion systems. We then examine major obstacles and prospects for application of direct-arc plasmas in this type of space thrusters.

Original language	English
Article number	7
Number of pages	63
Journal	Reviews of Modern Plasma Physics
Volume	3
Issue number	1
Early online date	11 Jun 2019
DOIs	https://doi.org/10.1007/s41614-019-0023-3
Publication status	Published - Dec 2019
Externally published	Yes

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Cite this

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title = "Direct current arc plasma thrusters for space applications: basic physics, design and perspectives",

abstract = "Renewed interest in space exploration and aspirations for colonization of Mars, Moon and possibly other extra-terrestrial bodies puts pressure on the present-day space technology to become more efficient. Space engines, or thrusters, are the key element of any spacecraft and thus, continuous improvement in thruster design and performance is needed to realize the mankind{\textquoteright}s goal of becoming a truly space faring civilization. Space micropropulsion systems that utilize plasma and electric fields to accelerate and expel mass to produce reactive thrust are advanced propulsion systems that can deliver very high specific impulse. In this review, we outline basic physical principles and design approaches for future direct-arc plasma propulsion systems. We then examine major obstacles and prospects for application of direct-arc plasmas in this type of space thrusters.",

keywords = "Arc discharge, Arc plasma propulsion, High-density plasma, Plasma acceleration, Space propulsion",

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AU - Zhou, H. P.

AU - Bazaka, K.

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AB - Renewed interest in space exploration and aspirations for colonization of Mars, Moon and possibly other extra-terrestrial bodies puts pressure on the present-day space technology to become more efficient. Space engines, or thrusters, are the key element of any spacecraft and thus, continuous improvement in thruster design and performance is needed to realize the mankind’s goal of becoming a truly space faring civilization. Space micropropulsion systems that utilize plasma and electric fields to accelerate and expel mass to produce reactive thrust are advanced propulsion systems that can deliver very high specific impulse. In this review, we outline basic physical principles and design approaches for future direct-arc plasma propulsion systems. We then examine major obstacles and prospects for application of direct-arc plasmas in this type of space thrusters.

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Direct current arc plasma thrusters for space applications: basic physics, design and perspectives

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