Abstract
Propulsion is a critical subsystem of many spacecraft1–4. For efficient propellant usage, electric propulsion systems based on the electrostatic acceleration of ions formed during electron impact ionization of a gas are particularly attractive5,6. At present, xenon is used almost exclusively as an ionizable propellant for space propulsion2–5. However, xenon is rare, it must be stored under high pressure and commercial production is expensive7–9. Here we demonstrate a propulsion system that uses iodine propellant and we present in-orbit results of this new technology. Diatomic iodine is stored as a solid and sublimated at low temperatures. A plasma is then produced with a radio-frequency inductive antenna, and we show that the ionization efficiency is enhanced compared with xenon. Both atomic and molecular iodine ions are accelerated by high-voltage grids to generate thrust, and a highly collimated beam can be produced with substantial iodine dissociation. The propulsion system has been successfully operated in space onboard a small satellite with manoeuvres confirmed using satellite tracking data. We anticipate that these results will accelerate the adoption of alternative propellants within the space industry and demonstrate the potential of iodine for a wide range of space missions. For example, iodine enables substantial system miniaturization and simplification, which provides small satellites and satellite constellations with new capabilities for deployment, collision avoidance, end-of-life disposal and space exploration10–14.
Highlights
As spacecraft are power limited, electric propulsion systems must maximize their thrust-to-power ratio, which for electrostatic accelerators requires a propellant with a low ionization threshold and a high atomic mass[5]
Solid diatomic iodine is stored in a tank connected to an inductively coupled plasma source tube terminated by two high-voltage, multi-aperture grids (Fig. 1)
Heaters connected to the tank cause iodine sublimation and subsequent gas flow into the source tube
Summary
Debris: actions that will prove vital for the long-term sustainability of the space industry[39]. R. (eds) Space Mission Analysis and Design (Microcosm Press, 2005). Fundamentals of Electric Propulsion: Ion and Hall Thrusters (John Wiley, 2008). 6. Levchenko, I. et al Perspectives, frontiers, and new horizons for plasma-based space electric propulsion. W. (eds) Space Propulsion Analysis and Design. Propellant alternatives for ion and Hall thrusters. V. Iodine propellant for electric propulsion: to be or not to be. Maturisation of iodine-fueled BIT3 RF ion thruster and RF neutralizer. Global model of an iodine gridded plasma thruster. K. et al Performance of an iodine-fueled radio-frequency ion-thruster. K. et al Ion thrusters for electric propulsion: scientific issues developing a niche technology into a game changer. H. et al Overview of iodine propellant Hall thruster development activities at NASA Glenn Research Center. General Mission Analysis Tool (GMAT), version R2018a (NASA Goddard Space Flight Center, 2020); https://software.nasa.gov/software/GSC-18094-1. To view a copy of this license, visit http://creativecommons.org/licenses/by/4.0/
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