Regolith-based lunar habitats: an engineering approach to radiation shielding

Sustainable human exploration of the Moon will largely rely on in-situ resource utilisation, such as using regolith in habitat construction. This paper investigates the relative effectiveness of a polymer-enriched regolith brick versus a multilayer configuration of bare regolith and successive polye...

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Veröffentlicht in:	CEAS space journal 2024, Vol.16 (6), p.667-676
Hauptverfasser:	Akisheva, Yulia, Gourinat, Yves, Guatelli, Susanna, Dossat, Cédric, Robin-Chabanne, Steven, Varotsou, Athina, Cowley, Aidan, Makaya, Advenit
Format:	Artikel
Sprache:	eng
Schlagworte:	Aerospace Technology and Astronautics Bricks Cosmic rays Engineering Equivalence Galactic cosmic rays Lunar surface Multilayers Original Paper Polyethylene Polyethylenes Polymers Protons Radiation Radiation dosage Radiation protection Radiation shielding Regolith Secondary emission
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container_title	CEAS space journal
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creator	Akisheva, Yulia Gourinat, Yves Guatelli, Susanna Dossat, Cédric Robin-Chabanne, Steven Varotsou, Athina Cowley, Aidan Makaya, Advenit
description	Sustainable human exploration of the Moon will largely rely on in-situ resource utilisation, such as using regolith in habitat construction. This paper investigates the relative effectiveness of a polymer-enriched regolith brick versus a multilayer configuration of bare regolith and successive polyethylene layers as a passive shielding solution, when irradiated with Galactic Cosmic Ray (GCR) protons. Radiation–matter interactions are simulated with RayXpert ® software and the dose equivalent in the ICRU sphere behind a representative habitat wall is calculated. The secondary emission of neutrons and protons from the shielding solution is studied as well. This work provides a quantitative insight into how much polymer is required to achieve a significant improvement in terms of radiation protection when compared to a bare regolith wall. At least 30–50% of polyethylene by mass is required to be added to a regolith mix to achieve a significant advantage in radiation protection capability vis-à-vis bare regolith. Multilayer solutions are far better in terms of radiation protection than the polymer-enriched regolith. For example, the thinnest polyethylene layer tested (0.78 cm), reduces the total dose equivalent by about 3.3%. Thicker polyethylene layers added behind a bare regolith brick reduce the total dose equivalent and the dose equivalent due to protons significantly. For instance, a multilayer with 23.4 cm of polyethylene reduces the total dose equivalent by 19%. The equivalent case of polymer–regolith mix (with 30% of polyethylene by mass) reduces the total dose equivalent only by 3%.
doi_str_mv	10.1007/s12567-024-00540-4
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subjects	Aerospace Technology and Astronautics Bricks Cosmic rays Engineering Equivalence Galactic cosmic rays Lunar surface Multilayers Original Paper Polyethylene Polyethylenes Polymers Protons Radiation Radiation dosage Radiation protection Radiation shielding Regolith Secondary emission
title	Regolith-based lunar habitats: an engineering approach to radiation shielding
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