Electrostatic precipitation of dust in the Martian atmosphere: Implications for the utilization of resources during future manned exploration missions

Future human missions to Mars will require the utilization of local resources for oxygen, fuel, and water. The In Situ Resource Utilization (ISRU) project is an active research endeavor at NASA to develop technologies that can enable cost effective ways to live off the land. The extraction of oxygen...

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Bibliographic Details
Published in:Journal of physics. Conference series 2011-12, Vol.327 (1), p.12048-14
Main Authors: Calle, C I, Thompson, S M, Cox, N D, Johansen, M R, Williams, B S, Hogue, M D, Clements, J S
Format: Article
Language:English
Subjects:
Atmosphere
Barometric pressure
Carbon dioxide
Coronas
Discharge
Dust
Dust control
Electric fields
Electrostatic charge
Electrostatic precipitation
Electrostatic precipitator dust
Electrostatic precipitators
In situ resources utilization
Manned Mars missions
Mars
Mars atmosphere
Mars dust
Mars environment
Particle charging
Physics
Precipitators
Streamer gas discharge
Utilization
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Summary:Future human missions to Mars will require the utilization of local resources for oxygen, fuel, and water. The In Situ Resource Utilization (ISRU) project is an active research endeavor at NASA to develop technologies that can enable cost effective ways to live off the land. The extraction of oxygen from the Martian atmosphere, composed primarily of carbon dioxide, is one of the most important goals of the Mars ISRU project. The main obstacle is the relatively large amount of dust present in the Martian atmosphere. This dust must be efficiently removed from atmospheric gas intakes for ISRU processing chambers. A common technique to achieve this removal on earth is by electrostatic precipitation, where large electrostatic fields are established in a localized region to charge, precipitate and collect dust particles. This technique is difficult to adapt to the Martian environment, with an atmospheric pressure of about one-hundredth of the terrestrial atmosphere. At these low pressures, the corona discharges required to implant an electrostatic charge to the particles to be collected is extremely difficult to sustain and the corona easily transitions to a glow/streamer discharge, which is unsuitable for particle charging. In this paper, we report on our successful efforts to establish a stable corona under Martian simulated conditions. We also present results on dust collecting efficiencies with an electrostatic precipitator prototype that could be effectively used on a future mission to the red planet.
ISSN:1742-6596
1742-6588
1742-6596
DOI:10.1088/1742-6596/327/1/012048