Structural deformation and transformation of θ′-Al2Cu precipitate in Al matrix via interfacial diffusion

Jiaqi Wang; Seungha Shin; Ali Yousefzadi Nobakht; Amit Shyam

doi:10.1016/j.commatsci.2018.09.024

Structural deformation and transformation of θ′-Al₂Cu precipitate in Al matrix via interfacial diffusion

Jiaqi Wang, Seungha Shin, Ali Yousefzadi Nobakht, Amit Shyam

Alloy Behavior & Design

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

16 Scopus citations

Abstract

Metastable θ′-Al₂Cu precipitates enhance mechanical properties of Al alloy, but gradually transform to θ phase due to diffusion related coarsening at higher temperatures (>200 °C). To improve understanding of the phase instability and transformation of θ′-Al₂Cu, we investigated the interfacial atomic mobility of θ′-Al₂Cu precipitate in Al matrix via molecular dynamics (MD). To characterize the interfacial atomic mobility, diffusion properties (activation energy, diffusivity, and jump attempt frequency) with respect to atomic species, interfacial structure, and temperature are calculated using atomic trajectories from MD. For the enhanced accuracy of this analysis, especially at low temperatures, temporal scale of molecular dynamics is significantly extended by employing the parallel replica dynamics. This study, as the first MD investigation on atomic diffusion of θ′-Al₂Cu in Al matrix, suggests and discusses (i) structural deformation activated at the semi-coherent θ′-Al₂Cu/Al interfaces, (ii) transformation initiated at the edge of the coherent θ′-Al₂Cu/Al interface, and (iii) directional dependence of diffusion properties. These findings are expected to be employed in a larger scale phase-field modeling of precipitate growth, and to contribute to the understanding of phase transformation process and the development of alloys with θ′-phase retained to higher temperatures.

Original language	English
Pages (from-to)	111-120
Number of pages	10
Journal	Computational Materials Science
Volume	156
DOIs	https://doi.org/10.1016/j.commatsci.2018.09.024
State	Published - Jan 2019

Funding

The authors acknowledged the financial support by Joint Development Research and Development (JDRD) program (Science Alliance) between University of Tennessee Knoxville and Oak Ridge National Laboratory . AS was supported by the Laboratory Directed Research and Development Program of ORNL , managed by UT-Battelle, LLC, for the US DOE. This work used the Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation grant number ACI-1053575 . JW appreciates helpful discussion and proofreading with Matthew H. Bowman, Jackson K. Wilt, James Dean Blanks, Justin Garner, and Cameron Wagner. The authors acknowledged the financial support by Joint Development Research and Development (JDRD) program (Science Alliance) between University of Tennessee Knoxville and Oak Ridge National Laboratory. AS was supported by the Laboratory Directed Research and Development Program of ORNL, managed by UT-Battelle, LLC, for the US DOE. This work used the Extreme Science and Engineering Discovery Environment (XSEDE), which is supported by National Science Foundation grant number ACI-1053575. JW appreciates helpful discussion and proofreading with Matthew H. Bowman, Jackson K. Wilt, James Dean Blanks, Justin Garner, and Cameron Wagner.

Keywords

Deformation
Interfacial diffusion
Parallel replica dynamics
Transformation
θ′-AlCu precipitate

Access to Document

10.1016/j.commatsci.2018.09.024

Cite this

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title = "Structural deformation and transformation of θ′-Al2Cu precipitate in Al matrix via interfacial diffusion",

abstract = "Metastable θ′-Al2Cu precipitates enhance mechanical properties of Al alloy, but gradually transform to θ phase due to diffusion related coarsening at higher temperatures (>200 °C). To improve understanding of the phase instability and transformation of θ′-Al2Cu, we investigated the interfacial atomic mobility of θ′-Al2Cu precipitate in Al matrix via molecular dynamics (MD). To characterize the interfacial atomic mobility, diffusion properties (activation energy, diffusivity, and jump attempt frequency) with respect to atomic species, interfacial structure, and temperature are calculated using atomic trajectories from MD. For the enhanced accuracy of this analysis, especially at low temperatures, temporal scale of molecular dynamics is significantly extended by employing the parallel replica dynamics. This study, as the first MD investigation on atomic diffusion of θ′-Al2Cu in Al matrix, suggests and discusses (i) structural deformation activated at the semi-coherent θ′-Al2Cu/Al interfaces, (ii) transformation initiated at the edge of the coherent θ′-Al2Cu/Al interface, and (iii) directional dependence of diffusion properties. These findings are expected to be employed in a larger scale phase-field modeling of precipitate growth, and to contribute to the understanding of phase transformation process and the development of alloys with θ′-phase retained to higher temperatures.",

keywords = "Deformation, Interfacial diffusion, Parallel replica dynamics, Transformation, θ′-AlCu precipitate",

author = "Jiaqi Wang and Seungha Shin and {Yousefzadi Nobakht}, Ali and Amit Shyam",

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AB - Metastable θ′-Al2Cu precipitates enhance mechanical properties of Al alloy, but gradually transform to θ phase due to diffusion related coarsening at higher temperatures (>200 °C). To improve understanding of the phase instability and transformation of θ′-Al2Cu, we investigated the interfacial atomic mobility of θ′-Al2Cu precipitate in Al matrix via molecular dynamics (MD). To characterize the interfacial atomic mobility, diffusion properties (activation energy, diffusivity, and jump attempt frequency) with respect to atomic species, interfacial structure, and temperature are calculated using atomic trajectories from MD. For the enhanced accuracy of this analysis, especially at low temperatures, temporal scale of molecular dynamics is significantly extended by employing the parallel replica dynamics. This study, as the first MD investigation on atomic diffusion of θ′-Al2Cu in Al matrix, suggests and discusses (i) structural deformation activated at the semi-coherent θ′-Al2Cu/Al interfaces, (ii) transformation initiated at the edge of the coherent θ′-Al2Cu/Al interface, and (iii) directional dependence of diffusion properties. These findings are expected to be employed in a larger scale phase-field modeling of precipitate growth, and to contribute to the understanding of phase transformation process and the development of alloys with θ′-phase retained to higher temperatures.

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