High temperature and strain-rate response of AA2124-SiC metal matrix composites
High temperature and strain-rate response of AA2124-SiC metal matrix composites
This paper presents the results of the study of the dynamic impact behaviour of the AA2124-SiC Metal Matrix Composite (MMC) material with different particle reinforcement sizes and qualities using a compressive Split-Hopkinson Pressure Bar (SHPB) apparatus. Mechanical tests were performed at strain rates 1000 s−1, 2000 s−1, and 3000 s−1 and at temperatures of room temperature (25 °C), 100 °C and 200 °C. Microstructural analyses were carried out on the samples pre and post-compression experiments to study the fracture characteristics and mechanisms of the MMC materials. The flow stress-strain, strain rate, temperature effects and deformation mechanism were investigated. The backscattered electron images show that a higher strain rate of deformation induces the formation of denser and smaller grain size of CuAl2 precipitates, especially in composites with smaller SiC particle sizes. Temperature has posed a minor effect on the microstructural change. Heating the samples close to a solution treatment temperature, and then followed by an air quenching has resulted in a fine dispersion of CuAl2 precipitates, as well as a high saturation for the materials with a higher volumetric fraction of SiC reinforcement. The SHPB compression results reveal that the 225XF material has developed the highest stress among all materials. For materials with a higher volumetric fraction of SiC reinforcement (225XE and 225XF), cracks and failures have appeared in the samples during high strain rate and high-temperature compression experiments, which is believed to be caused by the increased brittleness of the material as a result of intensified oxide phases.
Li, Xuan
ed01c0d5-68e0-4abe-8642-5b9ebf153314
Kim, Jin
d441185e-4bf9-4d5c-bcfb-35379fb87895
Roy, Anish
c786e694-46fc-4463-bbbb-ac2339d26fb9
Ayvar-Soberanis, Sabino
06ebd2f6-c77d-45c3-8533-c933dec6c290
20 October 2022
Li, Xuan
ed01c0d5-68e0-4abe-8642-5b9ebf153314
Kim, Jin
d441185e-4bf9-4d5c-bcfb-35379fb87895
Roy, Anish
c786e694-46fc-4463-bbbb-ac2339d26fb9
Ayvar-Soberanis, Sabino
06ebd2f6-c77d-45c3-8533-c933dec6c290
Li, Xuan, Kim, Jin, Roy, Anish and Ayvar-Soberanis, Sabino
(2022)
High temperature and strain-rate response of AA2124-SiC metal matrix composites.
Materials Science and Engineering: A, 856, [144014].
(doi:10.1016/j.msea.2022.144014).
Abstract
This paper presents the results of the study of the dynamic impact behaviour of the AA2124-SiC Metal Matrix Composite (MMC) material with different particle reinforcement sizes and qualities using a compressive Split-Hopkinson Pressure Bar (SHPB) apparatus. Mechanical tests were performed at strain rates 1000 s−1, 2000 s−1, and 3000 s−1 and at temperatures of room temperature (25 °C), 100 °C and 200 °C. Microstructural analyses were carried out on the samples pre and post-compression experiments to study the fracture characteristics and mechanisms of the MMC materials. The flow stress-strain, strain rate, temperature effects and deformation mechanism were investigated. The backscattered electron images show that a higher strain rate of deformation induces the formation of denser and smaller grain size of CuAl2 precipitates, especially in composites with smaller SiC particle sizes. Temperature has posed a minor effect on the microstructural change. Heating the samples close to a solution treatment temperature, and then followed by an air quenching has resulted in a fine dispersion of CuAl2 precipitates, as well as a high saturation for the materials with a higher volumetric fraction of SiC reinforcement. The SHPB compression results reveal that the 225XF material has developed the highest stress among all materials. For materials with a higher volumetric fraction of SiC reinforcement (225XE and 225XF), cracks and failures have appeared in the samples during high strain rate and high-temperature compression experiments, which is believed to be caused by the increased brittleness of the material as a result of intensified oxide phases.
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Accepted/In Press date: 12 September 2022
e-pub ahead of print date: 22 September 2022
Published date: 20 October 2022
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Local EPrints ID: 497967
URI: http://eprints.soton.ac.uk/id/eprint/497967
ISSN: 0921-5093
PURE UUID: e789f470-2b7a-4032-9912-0cb6f10df3b1
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Date deposited: 05 Feb 2025 17:46
Last modified: 22 Aug 2025 02:46
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Author:
Xuan Li
Author:
Jin Kim
Author:
Anish Roy
Author:
Sabino Ayvar-Soberanis
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