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Effect of Mo addition on the microstructure and hardness of ultrafine-grained Ni alloys processed by a combination of cryorolling and high-pressure torsion

Effect of Mo addition on the microstructure and hardness of ultrafine-grained Ni alloys processed by a combination of cryorolling and high-pressure torsion
Effect of Mo addition on the microstructure and hardness of ultrafine-grained Ni alloys processed by a combination of cryorolling and high-pressure torsion
An investigation was conducted to examine the effect of molybdenum (Mo) content on the grain size, lattice defect structure and hardness of nickel (Ni) processed by severe plastic deformation (SPD). The SPD processing was applied to Ni samples with low (~0.3 at.%) and high (~5 at.%) Mo concentrations by a consecutive application of cryorolling and high-pressure torsion (HPT). The grain size and the dislocation density were determined by scanning electron microscopy and X-ray line profile analysis, respectively. In addition, the hardness values in the centers, half-radius and peripheries of the HPT-processed disks was determined after ½, 5 and 20 turns. The results show the higher Mo content yields a dislocation density about two times larger and a grain size about 30% smaller. The smallest value of the grain size was ~125 nm and the highest measured dislocation density was ~60 × 1014 m?2 for Ni-5% Mo. For the higher Mo concentration, the dislocation arrangement parameter was larger indicating a less clustered dislocation structure due to the hindering effect of Mo on the rearrangement of dislocations into low energy configurations. The results show there is a good correlation between the dislocation density and the yield strength using the Taylor equation. The ? parameter in this equation is slightly lower for the higher Mo concentration in accordance with the less clustered dislocation structure.
0921-5093
92-100
Kapoor, Garima
47c47784-ec66-4e1e-97a0-1d61015bfc98
Huang, Yi
9f4df815-51c1-4ee8-ad63-a92bf997103e
Sarma, V. Subramanya
7d6e49a8-eec8-4f87-a124-d4b7a51e6777
Langdon, Terence G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Gubicza, Jenő
046ca28c-f226-40bc-a510-9f1bc0a3a29d
Kapoor, Garima
47c47784-ec66-4e1e-97a0-1d61015bfc98
Huang, Yi
9f4df815-51c1-4ee8-ad63-a92bf997103e
Sarma, V. Subramanya
7d6e49a8-eec8-4f87-a124-d4b7a51e6777
Langdon, Terence G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Gubicza, Jenő
046ca28c-f226-40bc-a510-9f1bc0a3a29d

Kapoor, Garima, Huang, Yi, Sarma, V. Subramanya, Langdon, Terence G. and Gubicza, Jenő (2017) Effect of Mo addition on the microstructure and hardness of ultrafine-grained Ni alloys processed by a combination of cryorolling and high-pressure torsion. Materials Science and Engineering: A, 688, 92-100. (doi:10.1016/j.msea.2017.01.104).

Record type: Article

Abstract

An investigation was conducted to examine the effect of molybdenum (Mo) content on the grain size, lattice defect structure and hardness of nickel (Ni) processed by severe plastic deformation (SPD). The SPD processing was applied to Ni samples with low (~0.3 at.%) and high (~5 at.%) Mo concentrations by a consecutive application of cryorolling and high-pressure torsion (HPT). The grain size and the dislocation density were determined by scanning electron microscopy and X-ray line profile analysis, respectively. In addition, the hardness values in the centers, half-radius and peripheries of the HPT-processed disks was determined after ½, 5 and 20 turns. The results show the higher Mo content yields a dislocation density about two times larger and a grain size about 30% smaller. The smallest value of the grain size was ~125 nm and the highest measured dislocation density was ~60 × 1014 m?2 for Ni-5% Mo. For the higher Mo concentration, the dislocation arrangement parameter was larger indicating a less clustered dislocation structure due to the hindering effect of Mo on the rearrangement of dislocations into low energy configurations. The results show there is a good correlation between the dislocation density and the yield strength using the Taylor equation. The ? parameter in this equation is slightly lower for the higher Mo concentration in accordance with the less clustered dislocation structure.

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Accepted/In Press date: 30 January 2017
e-pub ahead of print date: 31 January 2017
Published date: 14 March 2017
Organisations: Engineering Mats & Surface Engineerg Gp

Identifiers

Local EPrints ID: 405274
URI: http://eprints.soton.ac.uk/id/eprint/405274
DOI: doi:10.1016/j.msea.2017.01.104
ISSN: 0921-5093
PURE UUID: 8fcf7e99-44d0-4498-ace2-20ebd7557410
ORCID for Yi Huang: ORCID iD orcid.org/0000-0001-9259-8123
ORCID for Terence G. Langdon: ORCID iD orcid.org/0000-0003-3541-9250

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Date deposited: 02 Feb 2017 11:32
Last modified: 16 Mar 2024 04:07

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Contributors

Author: Garima Kapoor
Author: Yi Huang ORCID iD
Author: V. Subramanya Sarma
Author: Terence G. Langdon ORCID iD
Author: Jenő Gubicza

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