Synergy of tensile strength and ductility in a novel additively manufactured Al-Mg-Mn-Er-Zr alloy with a trilevel equiaxed heterogeneous structure

Jifei Hu; Wu Wei; Shengping Wen; Jianlei Bi; Jieming Gao; Xingkai Hou; Kunyuan Gao; Peng Qi; Tongbo Wang; Xiaorong Zhou; Yuyan Zhai; Xiaocheng Shi; Zuoren Nie

doi:10.1080/17452759.2024.2440039

Synergy of tensile strength and ductility in a novel additively manufactured Al-Mg-Mn-Er-Zr alloy with a trilevel equiaxed heterogeneous structure

Jifei Hu, Wu Wei, Shengping Wen, Jianlei Bi, Jieming Gao, Xingkai Hou, Kunyuan Gao, Peng Qi, Tongbo Wang, Xiaorong Zhou, Yuyan Zhai, Xiaocheng Shi, Zuoren Nie

Research output: Contribution to journal › Article › peer-review

Abstract

This study investigates a novel Al-Mg-Mn-Er-Zr alloy with high strength and elongation. The uneven distribution of L12-Al3Er and Al3(Er, Zr) phases in the molten pool structure results in a trilevel equiaxed heterogeneous structure in the alloy. The as-printed alloy exhibits various forms of Al3(Er, Zr) phases and Er-containing primary phases (such as Al3(Zr, Er)5), demonstrating an excellent
combination of strength (ultimate tensile strength of 531 MPa, yield strength of 455 MPa) and elongation (fracture elongation of 27%). The strengthening mechanism and strain distribution behaviour of the heterogeneous structure are explored to understand the alloy’s elongation and strength mechanism. The large equiaxed grains concentrated in the centre of the molten pool contribute to high elongation, while heterogeneous deformation-induced (HDI) strengthening caused by heterogeneous grains increases the strength. The ultrafine grains at the molten pool boundaries ensure that strength remains at a high level, achieving a good balance of strength and elongation.

Original language	English
Article number	e2440039
Journal	Virtual and Physical Prototyping
Volume	20
Issue number	1
Early online date	17 Dec 2024
DOIs	https://doi.org/10.1080/17452759.2024.2440039
Publication status	Published - 1 Jan 2025

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Hu, J., Wei, W., Wen, S., Bi, J., Gao, J., Hou, X., Gao, K., Qi, P., Wang, T., Zhou, X., Zhai, Y., Shi, X., & Nie, Z. (2025). Synergy of tensile strength and ductility in a novel additively manufactured Al-Mg-Mn-Er-Zr alloy with a trilevel equiaxed heterogeneous structure. Virtual and Physical Prototyping, 20(1), Article e2440039. https://doi.org/10.1080/17452759.2024.2440039

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abstract = "This study investigates a novel Al-Mg-Mn-Er-Zr alloy with high strength and elongation. The uneven distribution of L12-Al3Er and Al3(Er, Zr) phases in the molten pool structure results in a trilevel equiaxed heterogeneous structure in the alloy. The as-printed alloy exhibits various forms of Al3(Er, Zr) phases and Er-containing primary phases (such as Al3(Zr, Er)5), demonstrating an excellent combination of strength (ultimate tensile strength of 531 MPa, yield strength of 455 MPa) and elongation (fracture elongation of 27%). The strengthening mechanism and strain distribution behaviour of the heterogeneous structure are explored to understand the alloy{\textquoteright}s elongation and strength mechanism. The large equiaxed grains concentrated in the centre of the molten pool contribute to high elongation, while heterogeneous deformation-induced (HDI) strengthening caused by heterogeneous grains increases the strength. The ultrafine grains at the molten pool boundaries ensure that strength remains at a high level, achieving a good balance of strength and elongation.",

author = "Jifei Hu and Wu Wei and Shengping Wen and Jianlei Bi and Jieming Gao and Xingkai Hou and Kunyuan Gao and Peng Qi and Tongbo Wang and Xiaorong Zhou and Yuyan Zhai and Xiaocheng Shi and Zuoren Nie",

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AU - Hu, Jifei

AU - Wei, Wu

AU - Wen, Shengping

AU - Bi, Jianlei

AU - Gao, Jieming

AU - Hou, Xingkai

AU - Gao, Kunyuan

AU - Qi, Peng

AU - Wang, Tongbo

AU - Zhou, Xiaorong

AU - Zhai, Yuyan

AU - Shi, Xiaocheng

AU - Nie, Zuoren

PY - 2025/1/1

Y1 - 2025/1/1

N2 - This study investigates a novel Al-Mg-Mn-Er-Zr alloy with high strength and elongation. The uneven distribution of L12-Al3Er and Al3(Er, Zr) phases in the molten pool structure results in a trilevel equiaxed heterogeneous structure in the alloy. The as-printed alloy exhibits various forms of Al3(Er, Zr) phases and Er-containing primary phases (such as Al3(Zr, Er)5), demonstrating an excellent combination of strength (ultimate tensile strength of 531 MPa, yield strength of 455 MPa) and elongation (fracture elongation of 27%). The strengthening mechanism and strain distribution behaviour of the heterogeneous structure are explored to understand the alloy’s elongation and strength mechanism. The large equiaxed grains concentrated in the centre of the molten pool contribute to high elongation, while heterogeneous deformation-induced (HDI) strengthening caused by heterogeneous grains increases the strength. The ultrafine grains at the molten pool boundaries ensure that strength remains at a high level, achieving a good balance of strength and elongation.

AB - This study investigates a novel Al-Mg-Mn-Er-Zr alloy with high strength and elongation. The uneven distribution of L12-Al3Er and Al3(Er, Zr) phases in the molten pool structure results in a trilevel equiaxed heterogeneous structure in the alloy. The as-printed alloy exhibits various forms of Al3(Er, Zr) phases and Er-containing primary phases (such as Al3(Zr, Er)5), demonstrating an excellent combination of strength (ultimate tensile strength of 531 MPa, yield strength of 455 MPa) and elongation (fracture elongation of 27%). The strengthening mechanism and strain distribution behaviour of the heterogeneous structure are explored to understand the alloy’s elongation and strength mechanism. The large equiaxed grains concentrated in the centre of the molten pool contribute to high elongation, while heterogeneous deformation-induced (HDI) strengthening caused by heterogeneous grains increases the strength. The ultrafine grains at the molten pool boundaries ensure that strength remains at a high level, achieving a good balance of strength and elongation.

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DO - 10.1080/17452759.2024.2440039

M3 - Article

SN - 1745-2759

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JO - Virtual and Physical Prototyping

JF - Virtual and Physical Prototyping

IS - 1

M1 - e2440039

ER -

Synergy of tensile strength and ductility in a novel additively manufactured Al-Mg-Mn-Er-Zr alloy with a trilevel equiaxed heterogeneous structure

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