2016
DOI: 10.1016/j.asr.2016.01.006
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A parametric sizing model for Molten Regolith Electrolysis reactors to produce oxygen on the Moon

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Cited by 21 publications
(17 citation statements)
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“…'Yield' in this context is defined as weight of oxygen extracted divided by total weight of regolith processed. The carbothermal reduction of molten regolith at ~1600 °C (also requiring subsequent methanereforming and electrolysis steps; Rosenberg et al, 1992;Gustafson et al, 2006;Balasubramaniam, 2010;Sanders and Larson, 2012), and the direct electrolysis of molten regolith at >1600 °C Haskin, 1992, 1993;Vai et al 2010;Sirk 2010;Wang et al 2011;Schreiner 2016), are less feedstock-dependent and higher yielding (theoretically 10-20% and 20-30% respectively), but require the handling of molten regolith at extreme temperatures. Research has also been conducted into the use of molten fluoride salts as a flux to dissolve lunar regolith oxide simulants and related silicate rocks at 960 -1250 °C, and hence to extract a mixed alloy electrochemically; however, these processes rely on the solubility of the various oxides and the efficacy in terms of oxygen yield has not been quantified (Kesterke 1970;Liu et al 2017).…”
Section: Introductionmentioning
confidence: 99%
“…'Yield' in this context is defined as weight of oxygen extracted divided by total weight of regolith processed. The carbothermal reduction of molten regolith at ~1600 °C (also requiring subsequent methanereforming and electrolysis steps; Rosenberg et al, 1992;Gustafson et al, 2006;Balasubramaniam, 2010;Sanders and Larson, 2012), and the direct electrolysis of molten regolith at >1600 °C Haskin, 1992, 1993;Vai et al 2010;Sirk 2010;Wang et al 2011;Schreiner 2016), are less feedstock-dependent and higher yielding (theoretically 10-20% and 20-30% respectively), but require the handling of molten regolith at extreme temperatures. Research has also been conducted into the use of molten fluoride salts as a flux to dissolve lunar regolith oxide simulants and related silicate rocks at 960 -1250 °C, and hence to extract a mixed alloy electrochemically; however, these processes rely on the solubility of the various oxides and the efficacy in terms of oxygen yield has not been quantified (Kesterke 1970;Liu et al 2017).…”
Section: Introductionmentioning
confidence: 99%
“…Molten salt electrolysis of lunar oxides to produce oxygen and useful metals/alloys is also being considered. [280][281][282][283] Moon could then be a forward base for refuelling and replenishing essential supplies. The extra-terrestrial production of oxygen from CO 2 in the Martian atmosphere, [284][285][286] the gas making up 95 % of the atmospheric pressure of about 600 Pa, and metals from Martian regolith [287][288][289] are crucial if missions to Mars and beyond are to be sustained.…”
Section: Electrochemistry In Spacementioning
confidence: 99%
“…Electrolysis of ice in the permanently shadowed regions of Moon and liquefaction to liquid oxygen and hydrogen is an option. Molten salt electrolysis of lunar oxides to produce oxygen and useful metals/alloys is also being considered [280–283] . Moon could then be a forward base for refuelling and replenishing essential supplies.…”
Section: Introductionmentioning
confidence: 99%
“…ISRU will ensure the sustainability and energy efficiency of space exploration, reduce the cost of delivery from Earth, and minimize mission risks. Among the topics of current ISRU research are producing metals and construction materials by transforming local regolith and rocks [9,10], harvesting oxygen and hydrogen from minerals and water [10,11], and growing plants [12,13]. In this sense, the development of structurally sound composite materials with superior properties that can benefit from ISRU is crucial for preparing missions to the Moon.…”
Section: Introductionmentioning
confidence: 99%