Space micropropulsion systems for Cubesats and small satellites: From proximate targets to furthermost frontiers

Levchenko, Igor; Bazaka, Kateryna; Ding, Yongjie; Raitses, Yevgeny; Mazouffre, S.; Henning, Torsten; Klar, Peter J.; Shinohara, Shunjiro; Schein, J.; Garrigues, Laurent; Kim, Minkwan; Lev, Dan; Taccogna, F.; Boswell, Rod; Charles, Christine; Koizumi, Hiroyuki; Shen, Yan; Scharlemann, Carsten; Keidar, Michael; Xu, Shuyan

doi:10.1063/1.5007734

Cited by 268 publications

(108 citation statements)

References 155 publications

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“…Despite the odd-odd waveform having applied no direct electrical asymmetry to the plasma, there was still a non-zero modulation in the dc self-bias voltage, 5 (a). The mechanism for this modulation is attributed to the variation in the peak-to-peak voltage (2) and associated variation in the power deposited with phase offset, see figure 5 (b). The increased rf-power deposition in figure 5 (b) coincides with an increased ionization rate adjacent to the powered electrode in figure 5 (c).…”

Section: Expansion Tubementioning

confidence: 99%

Control of electron, ion and neutral heating in a radio-frequency electrothermal microthruster via dual-frequency voltage waveforms

Doyle¹,

Gibson²,

Boswell³

et al. 2019

Plasma Sources Sci. Technol.

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The development of low power micro-propulsion sources is of recent interest for application on miniature satellite platforms. Radio-frequency (rf) plasma electrothermal microthrusters can operate without a space-charge neutralizer and provide increased control of spatiotemporal power deposition. Further understanding of how the phase-resolved rf plasma heating mechanisms affect the phase-averaged bulk plasma properties, e.g. neutral gas temperature, could allow for in-flight tailoring of plasma thrusters. In this work, experimentally validated two-dimensional fluid-kinetic simulations were employed to study the spatially resolved electron and ion power deposition and neutral gas heating in a dual-frequency rf electrothermal microthruster operating at 1.5 Torr plenum pressure in argon. Experimental validation was performed through a comparison of the measured and simulated phase resolved Ar(2p 1 ) excitation rates, showing close agreement. Two types of dual-frequency voltage waveforms were investigated, and comprise the combination of a 13.56 MHz voltage waveform with 27.12 MHz and 40.68 MHz waveforms, respectively. Varying the phase offset of the higher harmonic relative to the fundamental 13.56 MHz voltage waveform was found to modulate the dc self-bias voltage by 11% and 3% of the maximum applied peak-to-peak voltage, respectively. The 13.56 MHz, 27.12 MHz dual-frequency voltage waveform provided the highest Electric propulsion (EP) sources are an established alternative to traditional cold-gas and monopropellant thrusters for employment on satellites 1,2 . The miniaturization of EP sources for micro-satellites is an increasingly important area of research, resulting in the development of new compact, low-power and charge-neutral 3 , prototypes 4-6 . Electrothermal EP sources are particularly suited to miniaturization as the maximum gas temperature typically scales inversely with the thruster volume 1 .One such electrothermal thruster is the Pocket Rocket, a low power (≤ 50 W) asymmetric radiofrequency (rf) capacitively coupled micro-thruster 7-13 . The Pocket Rocket operates at a relatively high pressure (≥ 133 Pa (1 Torr)) as this represents the Paschen (pressure × distance) minimum for ignition for the dimensions of the source 14 . The thruster is typically powered by a 12.8 -13.8 MHz rf voltage 15 , where power is deposited into the propellant primarily through ion-neutral charge exchange collisions in the powered electrode sheath 9,16 . Thrust is produced as the hot (1000 K) neutrals exit the thruster in an exhaust plume. As the exhaust is neutral no external neutralizer is required 17 .The thruster and power supply have recently been demonstrated to fit within a standard 1U CubeSat frame, as described in Ref. 2 and 15.The physically asymmetric geometry of the Pocket Rocket thruster ensures that a substantial negative dc self-bias voltage forms on the radial dielectric wall adjacent to the powered electrode 9 . This dc self-bias voltage forms to balance the net positive and negative fluxes onto the radial ...

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Section: Expansion Tubementioning

confidence: 99%

Control of electron, ion and neutral heating in a radio-frequency electrothermal microthruster via dual-frequency voltage waveforms

Doyle¹,

Gibson²,

Boswell³

et al. 2019

Plasma Sources Sci. Technol.

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“…While self‐healing is possibly the most attractive feature that the advanced materials could introduce at the “spacecraft level” (with the adaptivity and multi‐functionality being a secondary feature), the situation may change when advanced materials are discussed in relation to space thrusters, and specifically, electric propulsion thrusters that are undoubtedly the most promising type of propulsors for the future advanced and miniaturized spacecraft . Various mission segments require different characteristics of a thrust system, and this is currently achieved by the use of a set of different thrusters installed on the spacecraft.…”

Section: Key Innovations—materials Change Thrustersmentioning

confidence: 99%

“…Multi‐modal operation is still a challenge but advanced, nanostructured materials may be a solution capable of transforming the space thrust technology. [40a] On the other hand, the life of space thrusters still remains the issue and should be adequately addressed, with self‐healing still being of a paramount importance.…”

Section: Key Innovations—materials Change Thrustersmentioning

confidence: 99%

Advanced Materials for Next‐Generation Spacecraft

et al. 2018

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Spacecraft are expected to traverse enormous distances over long periods of time without an opportunity for maintenance, re‐fueling, or repair, and, for interplanetary probes, no on‐board crew to actively control the spacecraft configuration or flight path. Nevertheless, space technology has reached the stage when mining of space resources, space travel, and even colonization of other celestial bodies such as Mars and the Moon are being seriously considered. These ambitious aims call for spacecraft capable of self‐controlled, self‐adapting, and self‐healing behavior. It is a tough challenge to address using traditional materials and approaches for their assembly. True interplanetary advances may only be attained using novel self‐assembled and self‐healing materials, which would allow for realization of next‐generation spacecraft, where the concepts of adaptation and healing are at the core of every level of spacecraft design. Herein, recent achievements are captured and future directions in materials‐driven development of space technology outlined.

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“…Proponents of Mars colonization consider present space technology as nearing the stage when it will be able to provide the necessary level of reliability and efficiency required for the one way journey from Earth to Mars. Indeed, a recent example of successful firing of thrusters on Voyager 1 after 37 years of space operation attests to our ability to overcome such significant challenges of spacecraft development as longevity, reliability, and operational readiness decades after launching. Ongoing advances in nanotechnology and materials engineering enhanced reliability and expanded functionality of contemporary electronics and robotics while reducing device mass, volume, and power consumption .…”

Section: Mars Colonization—do We Need It?mentioning

confidence: 99%

Mars Colonization: Beyond Getting There

Levchenko

Mazouffre

et al. 2018

Global Challenges

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Colonization of Mars: As humans gradually overcome technological challenges of deep space missions, the possibility of exploration and colonization of extraterrestrial outposts is being seriously considered by space agencies and commercial entities alike. But should we do it just because we potentially can? Is such an undoubtedly risky adventure justified from the economic, legal, and ethical points of view? And even if it is, do we have a system of instruments necessary to effectively and fairly manage these aspects of colonization? In this essay, a rich diversity of current opinions on the pros and cons of Mars colonization voiced by space enthusiasts with backgrounds in space technology, economics, and materials science are examined.

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Space micropropulsion systems for Cubesats and small satellites: From proximate targets to furthermost frontiers

Cited by 268 publications

References 155 publications

Control of electron, ion and neutral heating in a radio-frequency electrothermal microthruster via dual-frequency voltage waveforms

Control of electron, ion and neutral heating in a radio-frequency electrothermal microthruster via dual-frequency voltage waveforms

Advanced Materials for Next‐Generation Spacecraft

Mars Colonization: Beyond Getting There

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