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Facile route to bulk ultrafine-grain steels for high strength and ductility

Facile route to bulk ultrafine-grain steels for high strength and ductility
Facile route to bulk ultrafine-grain steels for high strength and ductility
Steels with sub-micrometre grain sizes usually possess high toughness and strength, which makes them promising for lightweighting technologies and energy-saving strategies. So far, the industrial fabrication of ultrafine-grained (UFG) alloys, which generally relies on the manipulation of diffusional phase transformation, has been limited to steels with austenite-to-ferrite transformation1,2,3. Moreover, the limited work hardening and uniform elongation of these UFG steels1,4,5 hinder their widespread application. Here we report the facile mass production of UFG structures in a typical Fe–22Mn–0.6C twinning-induced plasticity steel by minor Cu alloying and manipulation of the recrystallization process through the intragranular nanoprecipitation (within 30 seconds) of a coherent disordered Cu-rich phase. The rapid and copious nanoprecipitation not only prevents the growth of the freshly recrystallized sub-micrometre grains but also enhances the thermal stability of the obtained UFG structure through the Zener pinning mechanism6. Moreover, owing to their full coherency and disordered nature, the precipitates exhibit weak interactions with dislocations under loading. This approach enables the preparation of a fully recrystallized UFG structure with a grain size of 800 ± 400 nanometres without the introduction of detrimental lattice defects such as brittle particles and segregated boundaries. Compared with the steel to which no Cu was added, the yield strength of the UFG structure was doubled to around 710 megapascals, with a uniform ductility of 45 per cent and a tensile strength of around 2,000 megapascals. This grain-refinement concept should be extendable to other alloy systems, and the manufacturing processes can be readily applied to existing industrial production lines.
0028-0836
Gao, Junheng
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Jiang, Suihe
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Zhang, Huairuo
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Huang, Yuhe
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Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Xu, Yidong
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Guan, Shaokang
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Bendersky, Leonid A.
a5087818-b3bb-4c06-a1ad-d32320d78be9
Davydov, Albert, V
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Wu, Yuan
3addc655-b037-4763-af79-e224fbfc4d85
Zhu, Huihui
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Wang, Yandong
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Lu, Zhaoping
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Rainforth, W. Mark
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Gao, Junheng
ff08c8df-b051-4ab1-bc03-3b6d68ab9d2e
Jiang, Suihe
2ffb109f-df20-43fc-9bb9-607bee57394a
Zhang, Huairuo
1b9e929e-e571-4a44-ad76-f3d6a8b72269
Huang, Yuhe
5f7cd073-a1d7-43f4-8950-41e6c3380e67
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Xu, Yidong
e65bc33d-6707-452d-afd8-b9b18edb352d
Guan, Shaokang
b2091b66-8b5a-4064-97b4-73878ad76943
Bendersky, Leonid A.
a5087818-b3bb-4c06-a1ad-d32320d78be9
Davydov, Albert, V
29794e33-d193-4ce1-b056-6d0c9e38017b
Wu, Yuan
3addc655-b037-4763-af79-e224fbfc4d85
Zhu, Huihui
1e04f79f-4724-4117-9602-9e109983a6a2
Wang, Yandong
10c413d0-aa97-4b16-b84f-9c86a45adade
Lu, Zhaoping
33e0322f-c987-46e1-a857-6ed7b7275241
Rainforth, W. Mark
7226983c-4ca1-4f0a-8191-02e3424dc98f

Gao, Junheng, Jiang, Suihe, Zhang, Huairuo, Huang, Yuhe, Guan, Dikai, Xu, Yidong, Guan, Shaokang, Bendersky, Leonid A., Davydov, Albert, V, Wu, Yuan, Zhu, Huihui, Wang, Yandong, Lu, Zhaoping and Rainforth, W. Mark (2021) Facile route to bulk ultrafine-grain steels for high strength and ductility. Nature, 590 (7845). (doi:10.1038/s41586-021-03246-3).

Record type: Article

Abstract

Steels with sub-micrometre grain sizes usually possess high toughness and strength, which makes them promising for lightweighting technologies and energy-saving strategies. So far, the industrial fabrication of ultrafine-grained (UFG) alloys, which generally relies on the manipulation of diffusional phase transformation, has been limited to steels with austenite-to-ferrite transformation1,2,3. Moreover, the limited work hardening and uniform elongation of these UFG steels1,4,5 hinder their widespread application. Here we report the facile mass production of UFG structures in a typical Fe–22Mn–0.6C twinning-induced plasticity steel by minor Cu alloying and manipulation of the recrystallization process through the intragranular nanoprecipitation (within 30 seconds) of a coherent disordered Cu-rich phase. The rapid and copious nanoprecipitation not only prevents the growth of the freshly recrystallized sub-micrometre grains but also enhances the thermal stability of the obtained UFG structure through the Zener pinning mechanism6. Moreover, owing to their full coherency and disordered nature, the precipitates exhibit weak interactions with dislocations under loading. This approach enables the preparation of a fully recrystallized UFG structure with a grain size of 800 ± 400 nanometres without the introduction of detrimental lattice defects such as brittle particles and segregated boundaries. Compared with the steel to which no Cu was added, the yield strength of the UFG structure was doubled to around 710 megapascals, with a uniform ductility of 45 per cent and a tensile strength of around 2,000 megapascals. This grain-refinement concept should be extendable to other alloy systems, and the manufacturing processes can be readily applied to existing industrial production lines.

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Accepted/In Press date: 16 November 2020
Published date: 11 February 2021

Identifiers

Local EPrints ID: 474206
URI: http://eprints.soton.ac.uk/id/eprint/474206
DOI: doi:10.1038/s41586-021-03246-3
ISSN: 0028-0836
PURE UUID: dc68ba41-d06c-406a-82e9-a67df12d8913
ORCID for Dikai Guan: ORCID iD orcid.org/0000-0002-3953-2878

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Date deposited: 15 Feb 2023 17:45
Last modified: 17 Mar 2024 04:17

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Contributors

Author: Junheng Gao
Author: Suihe Jiang
Author: Huairuo Zhang
Author: Yuhe Huang
Author: Dikai Guan ORCID iD
Author: Yidong Xu
Author: Shaokang Guan
Author: Leonid A. Bendersky
Author: Albert, V Davydov
Author: Yuan Wu
Author: Huihui Zhu
Author: Yandong Wang
Author: Zhaoping Lu
Author: W. Mark Rainforth

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