Revealing relationships between microstructure and hardening nature of additively manufactured 316L stainless steel

Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated experimental efforts and calculations, the evolution of microstructure entities such as dislocation density, organization, cellular structure and rec...

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Published inMaterials & design Vol. 198; p. 109385
Main Authors Cui, Luqing, Jiang, Shuang, Xu, Jinghao, Peng, Ru Lin, Mousavian, Reza Taherzadeh, Moverare, Johan
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 15.01.2021
Elsevier
Subjects
316 L stainless steel
Dislocation-type
Hardening nature
Laser powder bed fusion
Microstructural evolution
Hardening nature
Laser powder bed fusion
Microstructural evolution
316 L stainless steel
Dislocation-type
316L stainless steel
Online AccessGet full text
ISSN0264-1275
0261-3069
1873-4197
DOI10.1016/j.matdes.2020.109385

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Abstract Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated experimental efforts and calculations, the evolution of microstructure entities such as dislocation density, organization, cellular structure and recrystallization behaviors were characterized as a function of heat treatments. Furthermore, the evolution of dislocation-type, namely the geometrically necessary dislocations (GNDs) and statistically stored dislocations (SSDs), and their impacts on the hardness variation during annealing treatments for L-PBF alloy were experimentally investigated. The GND and SSD densities were statistically measured utilizing the Hough-based EBSD method and Taylor's hardening model. With the progress of recovery, the GNDs migrate from cellular walls to more energetically-favourable regions, resulting in the higher concentration of GNDs along subgrain boundaries. The SSD density decreases faster than the GND density during heat treatments, because the SSD density is more sensitive to the release of thermal distortions formed in printing. In all annealing conditions, the dislocations contribute to more than 50% of the hardness, and over 85.8% of the total dislocations are GNDs, while changes of other strengthening mechanism contributions are negligible, which draws a conclusion that the hardness of the present L-PBF alloy is governed predominantly by GNDs. [Display omitted] •Dislocation-type and their impacts on hardening nature of L-PBF alloys during annealing were studied.•GND and SSD densities were statistically measured utilizing Hough-based EBSD method and Taylor's hardening model.•Migration of GNDs during recovery leads to higher concentration of GNDs along new subgrain boundaries.•SSDs decrease faster than GNDs during annealing, because SSDs largely depend on the release of thermal distortions.•GND type dislocations governing the hardening nature of the present L-PBF alloys.
AbstractList Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated experimental efforts and calculations, the evolution of microstructure entities such as dislocation density, organization, cellular structure and recrystallization behaviors were characterized as a function of heat treatments. Furthermore, the evolution of dislocation-type, namely the geometrically necessary dislocations (GNDs) and statistically stored dislocations (SSDs), and their impacts on the hardness variation during annealing treatments for L-PBF alloy were experimentally investigated. The GND and SSD densities were statistically measured utilizing the Hough-based EBSD method and Taylor's hardening model. With the progress of recovery, the GNDs migrate from cellular walls to more energetically-favourable regions, resulting in the higher concentration of GNDs along subgrain boundaries. The SSD density decreases faster than the GND density during heat treatments, because the SSD density is more sensitive to the release of thermal distortions formed in printing. In all annealing conditions, the dislocations contribute to more than 50% of the hardness, and over 85.8% of the total dislocations are GNDs, while changes of other strengthening mechanism contributions are negligible, which draws a conclusion that the hardness of the present L-PBF alloy is governed predominantly by GNDs.
Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated experimental efforts and calculations, the evolution of microstructure entities such as dislocation density, organization, cellular structure and recrystallization behaviors were characterized as a function of heat treatments. Furthermore, the evolution of dislocation-type, namely the geometrically necessary dislocations (GNDs) and statistically stored dislocations (SSDs), and their impacts on the hardness variation during annealing treatments for L-PBF alloy were experimentally investigated. The GND and SSD densities were statistically measured utilizing the Hough-based EBSD method and Taylor's hardening model. With the progress of recovery, the GNDs migrate from cellular walls to more energetically-favourable regions, resulting in the higher concentration of GNDs along subgrain boundaries. The SSD density decreases faster than the GND density during heat treatments, because the SSD density is more sensitive to the release of thermal distortions formed in printing. In all annealing conditions, the dislocations contribute to more than 50% of the hardness, and over 85.8% of the total dislocations are GNDs, while changes of other strengthening mechanism contributions are negligible, which draws a conclusion that the hardness of the present L-PBF alloy is governed predominantly by GNDs. [Display omitted] •Dislocation-type and their impacts on hardening nature of L-PBF alloys during annealing were studied.•GND and SSD densities were statistically measured utilizing Hough-based EBSD method and Taylor's hardening model.•Migration of GNDs during recovery leads to higher concentration of GNDs along new subgrain boundaries.•SSDs decrease faster than GNDs during annealing, because SSDs largely depend on the release of thermal distortions.•GND type dislocations governing the hardening nature of the present L-PBF alloys.
Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated experimental efforts and calculations, the evolution of microstructure entities such as dislocation density, organization, cellular structure and recrystallization behaviors were characterized as a function of heat treatments. Furthermore, the evolution of dislocation-type, namely the geometrically necessary dislocations (GNDs) and statistically stored dislocations (SSDs), and their impacts on the hardness variation during annealing treatments for L-PBF alloy were experimentally investigated. The GND and SSD densities were statistically measured utilizing the Hough-based EBSD method and Taylor's hardening model. With the progress of recovery, the GNDs migrate from cellular walls to more energetically-favourable regions, resulting in the higher concentration of GNDs along subgrain boundaries. The SSD density decreases faster than the GND density during heat treatments, because the SSD density is more sensitive to the release of thermal distortions formed in printing. In all annealing conditions, the dislocations contribute to more than 50% of the hardness, and over 85.8% of the total dislocations are GNDs, while changes of other strengthening mechanism contributions are negligible, which draws a conclusion that the hardness of the present L-PBF alloy is governed predominantly by GNDs.
ArticleNumber 109385
Author Jiang, Shuang
Peng, Ru Lin
Xu, Jinghao
Mousavian, Reza Taherzadeh
Cui, Luqing
Moverare, Johan
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  givenname: Ru Lin
  surname: Peng
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  organization: Division of Engineering Materials, Department of Management and Engineering, Linköping University, Linköping SE-58183, Sweden
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Keywords Hardening nature
Laser powder bed fusion
Microstructural evolution
316 L stainless steel
Dislocation-type
316L stainless steel
Language English
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Snippet Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated...
Relationships between microstructures and hardening nature of laser powder bed fused (L-PBF) 316 L stainless steel have been studied. Using integrated...
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StartPage 109385
SubjectTerms 316 L stainless steel
Dislocation-type
Hardening nature
Laser powder bed fusion
Microstructural evolution
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Title Revealing relationships between microstructure and hardening nature of additively manufactured 316L stainless steel
URI https://dx.doi.org/10.1016/j.matdes.2020.109385
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