Understanding process parameter-induced variability for tailoring precipitation behavior, grain structure, and mechanical properties of Al-Mg-Si-Mn alloy during solid-state additive manufacturing
Understanding process parameter-induced variability for tailoring precipitation behavior, grain structure, and mechanical properties of Al-Mg-Si-Mn alloy during solid-state additive manufacturing
Additive friction stir deposition (AFSD), a solid-state additive manufacturing technique, has excellent industrial application potential, particularly for Al alloys. However, in-depth process parameter-microstructure-property correlations are lacking, especially regarding precipitation behavior. In this work, AFSD of Al-Mg-Si-Mn alloy with various process parameter combinations was performed to understand the variation (by ∼ 70 %) in the nano/microhardness, concerning the precipitation behavior. The low nano/microhardness sample exhibited dissolution of the β” strengthening phase. However, higher nano/microhardness samples showed varying microstructural features with high dislocation density owing to fine-scale pre-β” precipitation and another sample possessed inhomogeneous β” phase distribution and β’ precipitation at the grain boundaries, thus exhibiting reprecipitation during AFSD. The variation in the grain structure was such that the high nano/microhardness samples exhibited large, elongated grains (∼11 to 13 µm) and low recrystallization fractions (∼16 –18 %) suggesting a predominantly non-recrystallized microstructure. Conversely, the lowest nano/microhardness sample exhibited the smallest grain size (∼5 µm) and, a higher recrystallization fraction (∼42 %). These findings demonstrate extensive variation in the precipitation behavior, grain structure, and mechanical properties due to the process parameters. Future applications can leverage this knowledge to tailor the microstructure and mechanical properties based on the identified process parameter combinations.
Additive friction stir deposition (AFSD), Additive manufacturing, Mechanical properties, Microstructure, Process parameter
Pariyar, Abhishek
125d12ff-fd20-4618-a0d2-2c459ba40769
Yasa, Evren
f66abf78-7ef0-4c65-921d-2d81aab0a146
Sharman, Adrian
988e67d6-109b-4da9-82aa-f0d03e543c44
Perugu, Chandra S.
60fe393d-36c6-4755-b8ef-c19e02def941
Yuan, Liang
c1ac62cb-5b14-40e5-ac61-c0a6559de48f
Hughes, James
8e70a378-650d-4be8-93b2-133263595210
Guan, Dikai
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20 August 2024
Pariyar, Abhishek
125d12ff-fd20-4618-a0d2-2c459ba40769
Yasa, Evren
f66abf78-7ef0-4c65-921d-2d81aab0a146
Sharman, Adrian
988e67d6-109b-4da9-82aa-f0d03e543c44
Perugu, Chandra S.
60fe393d-36c6-4755-b8ef-c19e02def941
Yuan, Liang
c1ac62cb-5b14-40e5-ac61-c0a6559de48f
Hughes, James
8e70a378-650d-4be8-93b2-133263595210
Guan, Dikai
d20c4acc-342a-43fa-a204-7283f0cc33bf
Pariyar, Abhishek, Yasa, Evren, Sharman, Adrian, Perugu, Chandra S., Yuan, Liang, Hughes, James and Guan, Dikai
(2024)
Understanding process parameter-induced variability for tailoring precipitation behavior, grain structure, and mechanical properties of Al-Mg-Si-Mn alloy during solid-state additive manufacturing.
Materials & Design, 245, [113238].
(doi:10.1016/j.matdes.2024.113238).
Abstract
Additive friction stir deposition (AFSD), a solid-state additive manufacturing technique, has excellent industrial application potential, particularly for Al alloys. However, in-depth process parameter-microstructure-property correlations are lacking, especially regarding precipitation behavior. In this work, AFSD of Al-Mg-Si-Mn alloy with various process parameter combinations was performed to understand the variation (by ∼ 70 %) in the nano/microhardness, concerning the precipitation behavior. The low nano/microhardness sample exhibited dissolution of the β” strengthening phase. However, higher nano/microhardness samples showed varying microstructural features with high dislocation density owing to fine-scale pre-β” precipitation and another sample possessed inhomogeneous β” phase distribution and β’ precipitation at the grain boundaries, thus exhibiting reprecipitation during AFSD. The variation in the grain structure was such that the high nano/microhardness samples exhibited large, elongated grains (∼11 to 13 µm) and low recrystallization fractions (∼16 –18 %) suggesting a predominantly non-recrystallized microstructure. Conversely, the lowest nano/microhardness sample exhibited the smallest grain size (∼5 µm) and, a higher recrystallization fraction (∼42 %). These findings demonstrate extensive variation in the precipitation behavior, grain structure, and mechanical properties due to the process parameters. Future applications can leverage this knowledge to tailor the microstructure and mechanical properties based on the identified process parameter combinations.
Text
Revised_New first paper 28-07-2024 2024 Mat and Des DG revised
- Accepted Manuscript
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supplementary 5th draft 29-07-2024
- Accepted Manuscript
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1-s2.0-S0264127524006130-main
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Accepted/In Press date: 9 August 2024
e-pub ahead of print date: 14 August 2024
Published date: 20 August 2024
Keywords:
Additive friction stir deposition (AFSD), Additive manufacturing, Mechanical properties, Microstructure, Process parameter
Identifiers
Local EPrints ID: 493546
URI: http://eprints.soton.ac.uk/id/eprint/493546
ISSN: 0261-3069
PURE UUID: 3b62636f-be00-4bfe-9380-0e37414f87c3
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Date deposited: 05 Sep 2024 17:14
Last modified: 06 Sep 2024 02:06
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Contributors
Author:
Abhishek Pariyar
Author:
Evren Yasa
Author:
Adrian Sharman
Author:
Chandra S. Perugu
Author:
Liang Yuan
Author:
James Hughes
Author:
Dikai Guan
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