Effect of ce content on properties of al-ce-based composites by powder-in-tube method

Mairym Vázquez, Oscar Marcelo Suárez, Michael Thompson, Haneul Jang, Na Gong, David Weiss, Orlando Rios

Research output: Contribution to journalArticlepeer-review

2 Scopus citations

Abstract

Al-Ce based alloys have gained recent interest and have proven to have excellent strength without heat treatment and high thermal stability. Challenges with the production of Al-Ce samples from elemental powders arise due to the elemental material before alloying being susceptible to rapid oxidation. The methodology for making superconductive wire, powder-in-tube, was used as a consolidate Al and Ce elemental powder, and Al-8 wt % Ce-10 wt % Mg composite powder into bulk nanostructured material. Powder samples are fabricated in an inert controlled atmosphere, then sealed in a tube to avoid oxidation of powders. Therefore, most of the powder is used without much loss. We used 316 stainless-steel tubes as a sheathing material. For Al-xCe wt % (x = 8 to 14) samples of elemental powder, liquid phase sintering was used and for Al-Ce-Mg powder solid-state sintering. Characterization of the bulk consolidated material after sintering, and before and after heat treatment, was made using optical and Scanning Electron Microscope imaging, Energy Dispersive Spectroscopy, Microhardness and Rockwell Hardness test. We demonstrated that microstructure stability in Al-Ce-based specimens can be retained after thermomechanical processing. Densification was achieved and oxidation of powder was avoided in most samples. In addition, we found that Fe and Ni in the sheathing material react with Al in the process, and Ce concentration modifies the reactivity the sheath.

Original languageEnglish
Article number255
JournalJournal of Composites Science
Volume5
Issue number10
DOIs
StatePublished - Oct 2021
Externally publishedYes

Funding

Funding: Financial support has been provided by the Transformational Initiative for Graduate ucation and Research (TIGER) project through a grant by the US Department of Education, Title V, Financial support has been provided by the Transformational Initiative for Graduate Education and Research (TIGER) project through a grant by the US Department of Education, Title V, Part B, Promoting Postbaccalaureate Opportunities for Hispanic Americans (PPOHA) Program (#P031M140035) and Extramural Research Experience Award (EREA). Laboratory space and equipment has been provided by the Nanotechnology Center for Biomedical, Environmental and Sustainability Applications Phase II. As part of the said Center, this research is based upon work supported by the National Science Foundation under Grant HRD 1345156. Finally, this research was also partially sponsored by the Critical Materials Institute, an Energy Innovation Hub funded by the U.S. Department of Energy (DOE), Office of Energy Efficiency and Renewable Energy, and Eck Industries.

FundersFunder number
Critical Materials Institute
Eck Industries
Transformational Initiative for Graduate Education and Research
U.S. Industries
National Science FoundationHRD 1345156
U.S. Department of Energy
U.S. Department of Education031M140035
Office of Energy Efficiency and Renewable Energy

    Keywords

    • Al-Ce-Mg
    • Aluminum
    • Aluminum composites
    • Cerium
    • Nanostructured materials
    • Powder consolidation
    • Powder metallurgy
    • Powder-in-tube

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