Additively manufactured electrohydrodynamic ionic liquid pure-ion sources for nanosatellite propulsion

This study reports the design, fabrication, and characterization of novel, low-cost, additively manufactured, miniaturized, multiplexed electrospray sources with zinc oxide nanowire (ZnONW)-based nanofluidics that produce, in both polarities, pure ions from ionic liquids. The devices comprise an emi...

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Bibliographic Details
Published in:Additive manufacturing 2020-12, Vol.36, p.101719, Article 101719
Main Authors: Máximo, Dulce Viridiana Melo, Velásquez-García, Luis Fernando
Format: Article
Language:English
Subjects:
3D-printed microelectromechanical system
EMI-BF4
Ionic liquid ion source
Nanosatellite propulsion
Zinc oxide nanowire
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Summary:This study reports the design, fabrication, and characterization of novel, low-cost, additively manufactured, miniaturized, multiplexed electrospray sources with zinc oxide nanowire (ZnONW)-based nanofluidics that produce, in both polarities, pure ions from ionic liquids. The devices comprise an emitting electrode with a monolithic array of emitters and an extractor electrode that triggers the electrohydrodynamic emission of ions from the emitter tips. The emitters are solid cones coated with a nanoporous, hydrothermally grown ZnONW forest that transports ionic liquid to the emitter tips. The emitting electrodes are 3D-printed using either SS 316L via binder jetting or FunToDo Industrial Blend resin via vat polymerization. The extractor electrode is 3D-printed using SS 316L via binder jetting. Experimental characterization of the devices in vacuum using an external collector electrode and the ionic liquid EMI-BF4 shows bipolar pure-ion emission with maximum per-emitter current on the order of microamperes, maximum per-emitter thrust on the order of a fraction of a micronewton, and an average of ~95% beam transmission, resulting in 100% polydispersive efficiency and a significantly higher specific impulse for a given bias voltage compared to state-of-the-art devices. This development is of great interest for miniaturized spacecraft propulsion and focused ion beam applications. [Display omitted] •First validation of nanosatellite electrospray ionic liquid pure-ion rocket.•Devices are made of 3D-printed metal and resin and hydrothermally grown ZnONWs.•Devices have up to 85 emitters (27 emitters/cm2) with ZnONW-based nanofluidics.•Vacuum characterization (EMI-BF4) shows uniform, bipolar, pure-ion emission.•Devices attain higher polydispersive efficiency and Isp than the state-of-the-art.
ISSN:2214-8604
2214-7810
DOI:10.1016/j.addma.2020.101719