The University of Southampton
University of Southampton Institutional Repository

Structure and low-temperature micromechanical properties of as-cast and SPD-processed high-entropy Co25−xCr25Fe25Ni25Cx alloys

Structure and low-temperature micromechanical properties of as-cast and SPD-processed high-entropy Co25−xCr25Fe25Ni25Cx alloys
Structure and low-temperature micromechanical properties of as-cast and SPD-processed high-entropy Co25−xCr25Fe25Ni25Cx alloys
The effect of carbon additions on the structure and mechanical properties of high-entropy alloys Co25−xCr25Fe25Ni25Cx (x = 0, 1, 3, at. %) in two structural states, as-cast coarse-grained (CG) samples and nanocrystalline (NC) obtained by severe plastic deformation (SPD), was studied. The SPD was performed by high-pressure torsion at room temperature. The mechanical properties were investigated by microindentation in the temperature range of T = 77−300 K. It was found that in the as-cast state, all alloys had a dendritic microstructure and an inhomogeneous distribution of elements. At x = 0 and x = 1, the dendrites were enriched in iron and nickel, and the interdendrite regions were enriched in chromium. At x = 3, in the interdendrite regions, a eutectic consisting of a multicomponent matrix and fine eutectic dendrites of M7C3 carbide, where M is predominantly chromium, was formed. The main phase in alloys had an fcc lattice, while the solubility of carbon in it was about 1 at. %. SPD led to the effective refinement of the microstructure (the size of the coherent scattering regions was about 30−50 nm), to an increase in the dislocation density up to (1−1.5)⋅1015 m−2 and to an increase in the concentration of stacking faults. The microhardness of CG alloys at room temperature increased monotonically with increasing carbon concentration, while in NC alloys the maximum microhardness HV was achieved at 1 at. % of carbon. The reason for this anomalous behavior of the microhardness of NC alloys is an increase in the grain size and a decrease in the dislocation density in the alloy with x = 3 compared to the alloy with x = 1. As the temperature decreased from room temperature to the temperature of liquid nitrogen, the microhardness of CG and NC alloys increased by about 1.5−1.7 and 1.2−1.5 times, respectively, which indicates the thermally-activated nature of plastic deformation under the indenter. The results obtained indicate that the main role in the hardening of the CG alloys Co25−xCr25Fe25Ni25Cx is due to solid solution and dispersion hardening, while in NC alloys it is hardening due to a decrease in the grain size (according to the Hall-Petch relation) and an increase in the dislocation density (according to the Taylor relation).
high-entropy alloys, carbon alloying, microstructure, microhardness, severe plastic deformation, deformation mechanisms.
560–569
Levenets, A.V.
5ff480e7-14c4-4859-a9d2-f9c143919250
Rusakova, H.V.
6f03e600-c5e1-4bbc-84ae-e4c1c65b1b2c
Fomenko, L.S.
dc105d70-e556-4860-b427-161b7d3b1e00
Huang, Yi
9f4df815-51c1-4ee8-ad63-a92bf997103e
Kolodiy, I.V.
829f2018-ad74-4342-a613-007fd82be1c9
Vasilenko, R.L.
c9c4171d-bd88-44bf-ae3e-564f062f84b4
Tabachnikova, E.D.
1b8801ba-0eac-48a1-a0c6-e8486db4e2c9
Tikhonovsky, M.A.
a9b23820-d7b6-46f5-abba-b8658b1c4a41
Langdon, T.G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86
Levenets, A.V.
5ff480e7-14c4-4859-a9d2-f9c143919250
Rusakova, H.V.
6f03e600-c5e1-4bbc-84ae-e4c1c65b1b2c
Fomenko, L.S.
dc105d70-e556-4860-b427-161b7d3b1e00
Huang, Yi
9f4df815-51c1-4ee8-ad63-a92bf997103e
Kolodiy, I.V.
829f2018-ad74-4342-a613-007fd82be1c9
Vasilenko, R.L.
c9c4171d-bd88-44bf-ae3e-564f062f84b4
Tabachnikova, E.D.
1b8801ba-0eac-48a1-a0c6-e8486db4e2c9
Tikhonovsky, M.A.
a9b23820-d7b6-46f5-abba-b8658b1c4a41
Langdon, T.G.
86e69b4f-e16d-4830-bf8a-5a9c11f0de86

Levenets, A.V., Rusakova, H.V., Fomenko, L.S., Huang, Yi, Kolodiy, I.V., Vasilenko, R.L., Tabachnikova, E.D., Tikhonovsky, M.A. and Langdon, T.G. (2022) Structure and low-temperature micromechanical properties of as-cast and SPD-processed high-entropy Co25−xCr25Fe25Ni25Cx alloys. Low Temperature Physics, 48 (7), 560–569. (doi:10.1063/10.0011605).

Record type: Article

Abstract

The effect of carbon additions on the structure and mechanical properties of high-entropy alloys Co25−xCr25Fe25Ni25Cx (x = 0, 1, 3, at. %) in two structural states, as-cast coarse-grained (CG) samples and nanocrystalline (NC) obtained by severe plastic deformation (SPD), was studied. The SPD was performed by high-pressure torsion at room temperature. The mechanical properties were investigated by microindentation in the temperature range of T = 77−300 K. It was found that in the as-cast state, all alloys had a dendritic microstructure and an inhomogeneous distribution of elements. At x = 0 and x = 1, the dendrites were enriched in iron and nickel, and the interdendrite regions were enriched in chromium. At x = 3, in the interdendrite regions, a eutectic consisting of a multicomponent matrix and fine eutectic dendrites of M7C3 carbide, where M is predominantly chromium, was formed. The main phase in alloys had an fcc lattice, while the solubility of carbon in it was about 1 at. %. SPD led to the effective refinement of the microstructure (the size of the coherent scattering regions was about 30−50 nm), to an increase in the dislocation density up to (1−1.5)⋅1015 m−2 and to an increase in the concentration of stacking faults. The microhardness of CG alloys at room temperature increased monotonically with increasing carbon concentration, while in NC alloys the maximum microhardness HV was achieved at 1 at. % of carbon. The reason for this anomalous behavior of the microhardness of NC alloys is an increase in the grain size and a decrease in the dislocation density in the alloy with x = 3 compared to the alloy with x = 1. As the temperature decreased from room temperature to the temperature of liquid nitrogen, the microhardness of CG and NC alloys increased by about 1.5−1.7 and 1.2−1.5 times, respectively, which indicates the thermally-activated nature of plastic deformation under the indenter. The results obtained indicate that the main role in the hardening of the CG alloys Co25−xCr25Fe25Ni25Cx is due to solid solution and dispersion hardening, while in NC alloys it is hardening due to a decrease in the grain size (according to the Hall-Petch relation) and an increase in the dislocation density (according to the Taylor relation).

Text
Structure and Micromechanical - Accepted Manuscript
Download (1MB)

More information

Accepted/In Press date: 20 May 2022
e-pub ahead of print date: 1 July 2022
Keywords: high-entropy alloys, carbon alloying, microstructure, microhardness, severe plastic deformation, deformation mechanisms.

Identifiers

Local EPrints ID: 484579
URI: http://eprints.soton.ac.uk/id/eprint/484579
PURE UUID: df1d6e22-a6cc-4dae-b4d7-726e47878c59
ORCID for Yi Huang: ORCID iD orcid.org/0000-0001-9259-8123
ORCID for T.G. Langdon: ORCID iD orcid.org/0000-0003-3541-9250

Catalogue record

Date deposited: 17 Nov 2023 17:51
Last modified: 17 Mar 2024 03:25

Export record

Altmetrics

Contributors

Author: A.V. Levenets
Author: H.V. Rusakova
Author: L.S. Fomenko
Author: Yi Huang ORCID iD
Author: I.V. Kolodiy
Author: R.L. Vasilenko
Author: E.D. Tabachnikova
Author: M.A. Tikhonovsky
Author: T.G. Langdon ORCID iD

Download statistics

Downloads from ePrints over the past year. Other digital versions may also be available to download e.g. from the publisher's website.

View more statistics

Atom RSS 1.0 RSS 2.0

Contact ePrints Soton: eprints@soton.ac.uk

ePrints Soton supports OAI 2.0 with a base URL of http://eprints.soton.ac.uk/cgi/oai2

This repository has been built using EPrints software, developed at the University of Southampton, but available to everyone to use.

We use cookies to ensure that we give you the best experience on our website. If you continue without changing your settings, we will assume that you are happy to receive cookies on the University of Southampton website.

×