Insights into primary carbides and nanoparticles in an additively manufactured high-alloy steel
Insights into primary carbides and nanoparticles in an additively manufactured high-alloy steel
This paper reports the use of combined electron microscopy and small-angle neutron scattering (SANS) to probe into the compositional and size evolution of the primary carbides and nanoparticles (defined by a size threshold of 100 nm) in an additively manufactured high-alloy steel before and after heat treatment. The primary carbides exhibit marginal changes in their total volume fraction and size after the austenitising and tempering. However, those carbides located at the prior-austenite boundaries provide a pinning effect to impede grain growth during the austenitising. The grain size increases from 1.7 µm in the as-manufactured to 2.8 µm in the as-tempered conditions, resulting in a limited strength loss of 33–126 MPa as estimated by using the Hall-Petch relationship. Atom probe tomography, which offers atomic spatial resolution examining a sample volume of 6.6 × 105 nm3, reveals the presence of numerous V and Cr-enriched nanoparticles with sizes of 1 to 10 nm within the steel matrix after the tempering. In contrast, the complementary SANS which examines a significantly larger sample volume of 0.9 mm3 but lacking spatial resolution, provides nanoparticle size information. It reveals a radius reduction from 7.6 to 1.0 nm and a volume fraction increase from 1.6 % to 2.3 %, in the as-manufactured and as-tempered conditions, respectively. The nanoparticles induced during tempering can contribute to a strength enhancement of 691 MPa, primarily through the Orowan bypass mechanism. This suggests that the combination of limited prior-austenite grain growth and the presence of nanoparticles is the key factor responsible for the unprecedented material strength.
Additive manufacturing, Atom probe tomography, Carbides, Neutron scattering, Steel
Zhang, Huayue
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Peng, Hui
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Bagot, Paul A.J.
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Wang, Yiqiang
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Venero, Diego Alba
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Robertson, Stuart
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El-Fallah, Gebril M.A.M.
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Guo, Hongbo
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Moody, Michael P.
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Chen, Bo
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15 May 2024
Zhang, Huayue
becacff9-8f12-44c6-89d5-12de35ded9d0
Peng, Hui
d5f9d6f2-1695-4e07-9a09-9b363a54b632
Bagot, Paul A.J.
8a06c019-e7c4-4baf-a17f-fa4cf7f6ed1c
Wang, Yiqiang
277991a3-206b-4d58-b7f2-9b2ed08562f0
Venero, Diego Alba
ea5e439e-5e67-48ba-ab66-d5d78351ccd0
Robertson, Stuart
ebb1023c-a846-4b45-9d65-1c9b7f3bbf08
El-Fallah, Gebril M.A.M.
bba1a29d-15f1-40bb-9502-e0a2e1241039
Guo, Hongbo
e4443178-ab9c-47e6-b239-c7bd592cd39c
Moody, Michael P.
38c01198-88db-4a5f-a474-6a264a901125
Chen, Bo
be54a9a8-da2a-4e6f-ae0e-0b076be87daf
Zhang, Huayue, Peng, Hui, Bagot, Paul A.J., Wang, Yiqiang, Venero, Diego Alba, Robertson, Stuart, El-Fallah, Gebril M.A.M., Guo, Hongbo, Moody, Michael P. and Chen, Bo
(2024)
Insights into primary carbides and nanoparticles in an additively manufactured high-alloy steel.
Acta Materialia, 270, [119834].
(doi:10.1016/j.actamat.2024.119834).
Abstract
This paper reports the use of combined electron microscopy and small-angle neutron scattering (SANS) to probe into the compositional and size evolution of the primary carbides and nanoparticles (defined by a size threshold of 100 nm) in an additively manufactured high-alloy steel before and after heat treatment. The primary carbides exhibit marginal changes in their total volume fraction and size after the austenitising and tempering. However, those carbides located at the prior-austenite boundaries provide a pinning effect to impede grain growth during the austenitising. The grain size increases from 1.7 µm in the as-manufactured to 2.8 µm in the as-tempered conditions, resulting in a limited strength loss of 33–126 MPa as estimated by using the Hall-Petch relationship. Atom probe tomography, which offers atomic spatial resolution examining a sample volume of 6.6 × 105 nm3, reveals the presence of numerous V and Cr-enriched nanoparticles with sizes of 1 to 10 nm within the steel matrix after the tempering. In contrast, the complementary SANS which examines a significantly larger sample volume of 0.9 mm3 but lacking spatial resolution, provides nanoparticle size information. It reveals a radius reduction from 7.6 to 1.0 nm and a volume fraction increase from 1.6 % to 2.3 %, in the as-manufactured and as-tempered conditions, respectively. The nanoparticles induced during tempering can contribute to a strength enhancement of 691 MPa, primarily through the Orowan bypass mechanism. This suggests that the combination of limited prior-austenite grain growth and the presence of nanoparticles is the key factor responsible for the unprecedented material strength.
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Accepted/In Press date: 14 March 2024
e-pub ahead of print date: 16 March 2024
Published date: 15 May 2024
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© 2024 The Author(s)
Keywords:
Additive manufacturing, Atom probe tomography, Carbides, Neutron scattering, Steel
Identifiers
Local EPrints ID: 489850
URI: http://eprints.soton.ac.uk/id/eprint/489850
ISSN: 1359-6454
PURE UUID: 70491407-a1b0-4b01-9223-265111e0429c
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Date deposited: 03 May 2024 16:42
Last modified: 29 May 2024 02:09
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Contributors
Author:
Huayue Zhang
Author:
Hui Peng
Author:
Paul A.J. Bagot
Author:
Yiqiang Wang
Author:
Diego Alba Venero
Author:
Stuart Robertson
Author:
Gebril M.A.M. El-Fallah
Author:
Hongbo Guo
Author:
Michael P. Moody
Author:
Bo Chen
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