Radiation-resistant aluminium alloy for space missions in the extreme environment of the solar system

Radiation-resistant aluminium alloy for space missions in the extreme environment of the solar system

Future human-based exploration of our solar system requires the invention of materials that can resist harsh environments. Age-hardenable aluminium alloys would be attractive candidates for structural components in long-distance spacecrafts, but their radiation resistance to solar energetic particle...

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Bibliographic Details
Main Authors: Willenshofer, Patrick D, Tunes, Matheus A, Vo, Ho T, Stemper, Lukas, Renk, Oliver, Greaves, Graeme, Uggowitzer, Peter J, Pogatscher, Stefan
Format: Journal Article
Language:English
Published: 07-10-2022
Subjects:
Physics - Materials Science
Physics - Space Physics
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Summary:Future human-based exploration of our solar system requires the invention of materials that can resist harsh environments. Age-hardenable aluminium alloys would be attractive candidates for structural components in long-distance spacecrafts, but their radiation resistance to solar energetic particles is insufficient. Common hardening phases dissolve and displacement damage occurs in the alloy matrix, which strongly degrades properties. Here we present an alloy where hardening is achieved by T-phase, featuring a giant unit cell and highly-negative enthalpy of formation. The phase shows record radiation survivability and can stabilize an ultrafine-grained structure upon temperature and radiation in the alloy, therby successfully preventing displacement damage to occur. Such concept can be considered ideal for the next-generation space materials and the design of radiation resistant alloy.
DOI:10.48550/arxiv.2210.03397