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Matrix transformation of lunar regolith and its use as a feedstock for additive manufacturing

Nicholas I. Cool, Saul Perez-Beltran, Jing‐Xiang Cheng, Natalia Rivera-González, Daniel Bronner, Anita, Elbert Wang, Umme Zakira, Mehdi Farahbakhsh, Kaiwei Liu, Jia-Lin Hsu, Björn Birgisson, Sarbajit Banerjee

2023iScience10 citationsDOIOpen Access PDF

Abstract

Building a sustainable human habitat on the Moon requires advances in excavation, paving, and additive manufacturing to construct landing pads, surface transportation arteries, resilient shelters, and scientific outposts. Construction of infrastructure elements on the lunar surface necessitates exploration of the interfacial reactivity of locally sourced regolith and the adaptation of Earth-based construction techniques. Various crosslinking frameworks and sintering methods have been proposed as a means of consolidating lunar regolith into load-bearing structures but each have challenges related to incomplete understanding of reaction chemistry, excessive thermal budgets, and lack of universal applicability to different mineral components of regolith. We describe here a versatile experimental and computational study of the consolidation of a regolith simulant through formation of siloxane networks enmeshing mineral particles by surface dissolution-precipitation and polycondensation reactions. Furthermore, by tailoring the rheological properties of the formulation an additive manufacturing feedstock can be developed for the construction of lunar infrastructure.

Topics & Concepts

RegolithRaw materialAstrobiologySinteringMaterials scienceEnvironmental scienceNanotechnologyChemical engineeringChemistryMetallurgyEngineeringOrganic chemistryPhysicsPlanetary Science and ExplorationAdditive Manufacturing and 3D Printing TechnologiesCalcium Carbonate Crystallization and Inhibition
Matrix transformation of lunar regolith and its use as a feedstock for additive manufacturing | Litcius