A multiscale experimental analysis of mechanical properties and deformation behavior of sintered copper–silicon carbide composites enhanced by high-pressure torsion
A multiscale experimental analysis of mechanical properties and deformation behavior of sintered copper–silicon carbide composites enhanced by high-pressure torsion
Experiments were conducted to investigate, within the framework of a multiscale approach, the mechanical enhancement, deformation and damage behavior of copper–silicon carbide composites (Cu–SiC) fabricated by spark plasma sintering (SPS) and the combination of SPS with high-pressure torsion (HPT). The mechanical properties of the metal–matrix composites were determined at three different length scales corresponding to the macroscopic, micro- and nanoscale. Small punch testing was employed to evaluate the strength of composites at the macroscopic scale. Detailed analysis of microstructure evolution related to SPS and HPT, sample deformation and failure of fractured specimens was conducted using scanning and transmission electron microscopy. A microstructural study revealed changes in the damage behavior for samples processed by HPT and an explanation for this behavior was provided by mechanical testing performed at the micro- and nanoscale. The strength of copper samples and the metal–ceramic interface was determined by microtensile testing and the hardness of each composite component, corresponding to the metal matrix, metal–ceramic interface, and ceramic reinforcement, was measured using nano-indentation. The results confirm the advantageous effect of large plastic deformation on the mechanical properties of Cu–SiC composites and demonstrate the impact on these separate components on the deformation and damage type.
Nosewicz, S.
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Bazarnik, Piotr
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Clozel, Melanie
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Kurpaska, Lukasz
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Jenczyk, Piotr
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Jarzabek, Dariusz
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Chmielewski, Marcin
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Romelczyk-Baishya, B.
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Lewandowska, Malgorzata
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Pakieła, Zbigniew
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Huang, Yi
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Langdon, Terence G
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17 August 2021
Nosewicz, S.
7e211113-c3ee-4bab-b7f6-4710b03ed3fc
Bazarnik, Piotr
844b4a15-226a-4275-9cee-812669fa033c
Clozel, Melanie
f3fa793c-9d90-4abd-8972-4c77f7ad5e79
Kurpaska, Lukasz
b9542f3a-03f8-4d46-964d-0a61c4780276
Jenczyk, Piotr
1ca281bf-eefb-4749-bb56-ad5882e87bd6
Jarzabek, Dariusz
1f70e1c7-2971-42a7-b907-08ce600faf68
Chmielewski, Marcin
20a641ea-7934-4094-a03f-30f840e6b3e9
Romelczyk-Baishya, B.
8b5a8510-b1c5-40ab-b004-acd001ac6074
Lewandowska, Malgorzata
c574d02d-d34d-4164-8ed1-90c3d77584d2
Pakieła, Zbigniew
0965fcab-231a-4a83-a1da-9f02fafc0989
Huang, Yi
a6cf243e-6fa1-4ecc-8833-add78a5bf47c
Langdon, Terence G
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Nosewicz, S., Bazarnik, Piotr, Clozel, Melanie, Kurpaska, Lukasz, Jenczyk, Piotr, Jarzabek, Dariusz, Chmielewski, Marcin, Romelczyk-Baishya, B., Lewandowska, Malgorzata, Pakieła, Zbigniew, Huang, Yi and Langdon, Terence G
(2021)
A multiscale experimental analysis of mechanical properties and deformation behavior of sintered copper–silicon carbide composites enhanced by high-pressure torsion.
Archives of Civil and Mechanical Engineering, 21.
(doi:10.1007/s43452-021-00286-4).
Abstract
Experiments were conducted to investigate, within the framework of a multiscale approach, the mechanical enhancement, deformation and damage behavior of copper–silicon carbide composites (Cu–SiC) fabricated by spark plasma sintering (SPS) and the combination of SPS with high-pressure torsion (HPT). The mechanical properties of the metal–matrix composites were determined at three different length scales corresponding to the macroscopic, micro- and nanoscale. Small punch testing was employed to evaluate the strength of composites at the macroscopic scale. Detailed analysis of microstructure evolution related to SPS and HPT, sample deformation and failure of fractured specimens was conducted using scanning and transmission electron microscopy. A microstructural study revealed changes in the damage behavior for samples processed by HPT and an explanation for this behavior was provided by mechanical testing performed at the micro- and nanoscale. The strength of copper samples and the metal–ceramic interface was determined by microtensile testing and the hardness of each composite component, corresponding to the metal matrix, metal–ceramic interface, and ceramic reinforcement, was measured using nano-indentation. The results confirm the advantageous effect of large plastic deformation on the mechanical properties of Cu–SiC composites and demonstrate the impact on these separate components on the deformation and damage type.
Text
Nosewicz-Archives-2021-final
- Accepted Manuscript
Text
s43452-021-00286-4
- Version of Record
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Accepted/In Press date: 8 August 2021
Published date: 17 August 2021
Identifiers
Local EPrints ID: 469707
URI: http://eprints.soton.ac.uk/id/eprint/469707
PURE UUID: 81bd127c-71a2-496c-98ee-dbe6007f6380
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Date deposited: 22 Sep 2022 16:46
Last modified: 17 Mar 2024 02:55
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Contributors
Author:
S. Nosewicz
Author:
Piotr Bazarnik
Author:
Melanie Clozel
Author:
Lukasz Kurpaska
Author:
Piotr Jenczyk
Author:
Dariusz Jarzabek
Author:
Marcin Chmielewski
Author:
B. Romelczyk-Baishya
Author:
Malgorzata Lewandowska
Author:
Zbigniew Pakieła
Author:
Yi Huang
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