Grain growth stagnation at 525 °C by nanoparticles in a solid-state additively manufactured Mg-4Y-3RE alloy
Grain growth stagnation at 525 °C by nanoparticles in a solid-state additively manufactured Mg-4Y-3RE alloy
Ultrafine-grained (UFG) materials exhibit high strengths due to grain boundary strengthening, but grains can grow rapidly if post heat treatment is required, making it challenging to achieve grain boundary and precipitation strengthening simultaneously. Grain growth stagnation at 525 °C (0.87 Tm, melting point) was observed in a Mg-4Y-3RE alloy fabricated by additive friction stir deposition (AFSD), a novel solid-state additive manufacturing technology. The AFSD processing produced a UFG microstructure and two major second phases, Mg41RE5 and nanoparticles containing Y and O. After solid solution treatment (SST) at 525 °C for 72 h, no noticeable grain growth occurred. While Mg41RE5 particles dissolved into the matrix within 4 h of SST, the nanoparticles remained stable and unaltered. The observed grain growth stagnation is attributed to Zener pinning by these thermally stable nanoparticles. These new findings offer a novel approach to designing UFG materials with exceptional thermal stability for high-temperature applications.
Additive friction stir deposition, Grain growth, Magnesium alloys, Nanoparticles, Ultrafine grained microstructure
4976-4987
Zhao, Xingjian
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Olden, Daniel
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Williams, Brady
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Pariyar, Abhishek
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Zhang, Dalong
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Murphy, Matthew
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Reed, Philippa
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Allison, Paul
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Jordon, Brian
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Qi, Jiahui
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Rainforth, W. Mark
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Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
8 January 2025
Zhao, Xingjian
58a8bb85-92c9-4e89-b4af-43d57fbe865f
Olden, Daniel
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Williams, Brady
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Pariyar, Abhishek
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Zhang, Dalong
910e3692-c673-4d93-8795-2f4f0107c942
Murphy, Matthew
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Reed, Philippa
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Allison, Paul
ceee19cb-c55c-411d-8963-939bad219e06
Jordon, Brian
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Qi, Jiahui
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Rainforth, W. Mark
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Guan, Dikai
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Zhao, Xingjian, Olden, Daniel, Williams, Brady, Pariyar, Abhishek, Zhang, Dalong, Murphy, Matthew, Reed, Philippa, Allison, Paul, Jordon, Brian, Qi, Jiahui, Rainforth, W. Mark and Guan, Dikai
(2025)
Grain growth stagnation at 525 °C by nanoparticles in a solid-state additively manufactured Mg-4Y-3RE alloy.
Journal of Magnesium and Alloys, 12 (12), .
(doi:10.1016/j.jma.2024.12.010).
Abstract
Ultrafine-grained (UFG) materials exhibit high strengths due to grain boundary strengthening, but grains can grow rapidly if post heat treatment is required, making it challenging to achieve grain boundary and precipitation strengthening simultaneously. Grain growth stagnation at 525 °C (0.87 Tm, melting point) was observed in a Mg-4Y-3RE alloy fabricated by additive friction stir deposition (AFSD), a novel solid-state additive manufacturing technology. The AFSD processing produced a UFG microstructure and two major second phases, Mg41RE5 and nanoparticles containing Y and O. After solid solution treatment (SST) at 525 °C for 72 h, no noticeable grain growth occurred. While Mg41RE5 particles dissolved into the matrix within 4 h of SST, the nanoparticles remained stable and unaltered. The observed grain growth stagnation is attributed to Zener pinning by these thermally stable nanoparticles. These new findings offer a novel approach to designing UFG materials with exceptional thermal stability for high-temperature applications.
Text
1-s2.0-S2213956724004079-main
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More information
Accepted/In Press date: 5 December 2024
e-pub ahead of print date: 20 December 2024
Published date: 8 January 2025
Keywords:
Additive friction stir deposition, Grain growth, Magnesium alloys, Nanoparticles, Ultrafine grained microstructure
Identifiers
Local EPrints ID: 497894
URI: http://eprints.soton.ac.uk/id/eprint/497894
ISSN: 2213-9567
PURE UUID: 2d86c50f-b700-4ccf-a50c-d7c5c976cfa7
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Date deposited: 04 Feb 2025 17:39
Last modified: 18 Sep 2025 02:08
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Contributors
Author:
Xingjian Zhao
Author:
Daniel Olden
Author:
Brady Williams
Author:
Abhishek Pariyar
Author:
Dalong Zhang
Author:
Matthew Murphy
Author:
Paul Allison
Author:
Brian Jordon
Author:
Jiahui Qi
Author:
W. Mark Rainforth
Author:
Dikai Guan
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