Microstructure refinement by a novel friction-based processing on Mg-Zn-Ca alloy
Research output: Contributions to collected editions/works › Article in conference proceedings › Research › peer-review
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Material Forming, ESAFORM 2024: The 27th International ESAFORM Conference on Material Forming – ESAFORM 2024. ed. / Anna Carla Araujo; Arthur Cantarel; France Chabert; Adrian Korycki; Philippe Olivier; Fabrice Schmidt. Millersville, PA : Association of American Publishers, 2024. p. 2031-2040 (Materials Research Proceedings; Vol. 41).
Research output: Contributions to collected editions/works › Article in conference proceedings › Research › peer-review
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TY - CHAP
T1 - Microstructure refinement by a novel friction-based processing on Mg-Zn-Ca alloy
AU - Chen, Ting
AU - Fu, Banglong
AU - Shen, Junjun
AU - Suhuddin, Uceu F.H.R.
AU - Wiese, Björn
AU - Dos Santos, Jorge F.
AU - Bergmann, Jean Pierre
AU - Klusemann, Benjamin
N1 - Publisher Copyright: © 2024, Association of American Publishers. All rights reserved.
PY - 2024
Y1 - 2024
N2 - Insufficient mechanical properties and uncontrollable degradation rates limit the wide application of Mg alloys in bioimplant materials. Microstructure refinement is a common method to improve both the mechanical properties and the corrosion resistance of Mg alloys. In order to efficiently obtain Mg alloys with fine microstructures for potential applications in bioimplant materials, a novel constrained friction processing (CFP) was proposed. In this work, the resulting compression properties of ZX10 alloy obtained by CFP with optimized processing parameter are reported. Additionally, the microstructure evolution during CFP was studied. The results show that during CFP, materials are subjected to high shear strain at the transition zone between the stir zone and thermo-mechanical affected zone, leading to recrystallization with strong local basal fiber shear texture. As the shoulder plunges down, the fraction of recrystallized grain and grain size increase. ZX10 alloy obtained by CFP exhibited higher compressive yield strength by more than 300% and ultimate compressive strength improves by 60%, which indicates the bright prospect of CFP for Mg processing.
AB - Insufficient mechanical properties and uncontrollable degradation rates limit the wide application of Mg alloys in bioimplant materials. Microstructure refinement is a common method to improve both the mechanical properties and the corrosion resistance of Mg alloys. In order to efficiently obtain Mg alloys with fine microstructures for potential applications in bioimplant materials, a novel constrained friction processing (CFP) was proposed. In this work, the resulting compression properties of ZX10 alloy obtained by CFP with optimized processing parameter are reported. Additionally, the microstructure evolution during CFP was studied. The results show that during CFP, materials are subjected to high shear strain at the transition zone between the stir zone and thermo-mechanical affected zone, leading to recrystallization with strong local basal fiber shear texture. As the shoulder plunges down, the fraction of recrystallized grain and grain size increase. ZX10 alloy obtained by CFP exhibited higher compressive yield strength by more than 300% and ultimate compressive strength improves by 60%, which indicates the bright prospect of CFP for Mg processing.
KW - Constrained Friction Processing
KW - Magnesium Alloys
KW - Microstructure
KW - Engineering
UR - http://www.scopus.com/inward/record.url?scp=85195986831&partnerID=8YFLogxK
U2 - 10.21741/9781644903131-224
DO - 10.21741/9781644903131-224
M3 - Article in conference proceedings
AN - SCOPUS:85195986831
T3 - Materials Research Proceedings
SP - 2031
EP - 2040
BT - Material Forming, ESAFORM 2024
A2 - Araujo, Anna Carla
A2 - Cantarel, Arthur
A2 - Chabert, France
A2 - Korycki, Adrian
A2 - Olivier, Philippe
A2 - Schmidt, Fabrice
PB - Association of American Publishers
CY - Millersville, PA
T2 - 27th International ESAFORM Conference on Material Forming, ESAFORM 2024
Y2 - 24 April 2024 through 26 April 2024
ER -