Fabrication and Evaluation of Large Alumina Crucibles by Vat Photopolymerization Additive Manufacturing for High-Temperature Actinide Chemistry

Authors

R. Joey Griffiths, Lawrence Livermore National Laboratory
Christy Santoyo, Lawerence Livermore National Laboratory
Jean-Baptise Forien, Lawerence Livermore National Laboratory
Bradley Childs, Lawerence Livermore National Laboratory
Andrew J. Swift, Lawerence Livermore National Laboratory
Andrew Cho, Lawerence Livermore National Laboratory
Alexander Wilson-Heid, Lawerence Livermore National Laboratory
George Ankrah, Brigham Young University - Provo
Devin Rappleye, Brigham Young University - ProvoFollow
Aiden A. Martin, Lawerence Livermore National Laboratory
Jason Jeffries, Lawerence Livermore National Laboratory
Kiel Holliday, Lawerence Livermore National Laboratory

Keywords

actinide, pyrochemistry, additive manufacturing, ceramics

Abstract

Additive manufacturing (AM) offers opportunities to advance the design and function of ceramic tooling in high temperature actinide pyrochemistry. In technical ceramics such as alumina, conventional forming techniques often restrict design flexibility and can limit experimental progress. In this study, we investigate the use of vat photopolymerization (VP) with commercial resins to fabricate large-scale alumina crucibles, reaching dimensions up to 125 mm, which is significantly larger than typically reported for dense VP ceramics. Notably, these additively manufactured components are produced using consumer-grade hardware, which limits process control, but offers significant upside in scalability and accessibility. Using microscopy and X-ray computed tomography, the VP alumina parts have high bulk densities above 95%, but also the prevalence of AM-induced artifacts and surface defects. Mechanical testing showed these defects to significantly reduce flexural strength and compromise part reliability. Electrorefining trials under sustained exposure to molten salts and metals reveal mixed results, with the AM material exhibiting high chemical compatibility, but mechanical failures due to the reduced strength were prevalent. Our findings illustrate both the promise and current limitations of AM ceramics for actinide chemistry, and point toward future improvements in process optimization, design strategies, and part screening to enhance performance and reliability.

Original Publication Citation

Griffiths, R. J., Santoyo, C., Forien, J.-B., Childs, B., Swift, A. J., Cho, A., Wilson-Heid, A., Ankrah, G., Rappleye, D., Martin, A. A., Jeffries, J., & Holliday, K. (2025). Fabrication and Evaluation of Large Alumina Crucibles by Vat Photopolymerization Additive Manufacturing for High-Temperature Actinide Chemistry. Applied Sciences, 15(23), 12742. https://doi.org/10.3390/app152312742

BYU ScholarsArchive Citation

Griffiths, R. Joey; Santoyo, Christy; Forien, Jean-Baptise; Childs, Bradley; Swift, Andrew J.; Cho, Andrew; Wilson-Heid, Alexander; Ankrah, George; Rappleye, Devin; Martin, Aiden A.; Jeffries, Jason; and Holliday, Kiel, "Fabrication and Evaluation of Large Alumina Crucibles by Vat Photopolymerization Additive Manufacturing for High-Temperature Actinide Chemistry" (2025). Faculty Publications. 8226.
https://scholarsarchive.byu.edu/facpub/8226

Document Type

Peer-Reviewed Article

Publication Date

2025-12-02

Publisher

Applied Sciences

Language

English

College

Ira A. Fulton College of Engineering

Department

Chemical Engineering

University Standing at Time of Publication

Assistant Professor

Copyright Status

© 2025 by the authors.

Copyright Use Information

https://lib.byu.edu/about/copyright/