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Atomistic study and continuum modeling of solute strengthening in slip-CTB interaction

[Display omitted] •The mechanism of solute affected slip-CTB interaction is investigated.•New metric to trigger the critical slip-CTB event is proposed based on MD simulation.•Continuum model for solution strengthening on slip-CTB interaction is established.•Criterion to determine the route of react...

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Published in:Computational materials science 2021-06, Vol.194, p.110430, Article 110430
Main Authors: Mao, Jianxing, Hu, Dianyin, Song, Jun, Meng, Fanchao, Wang, Rongqiao
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Language:English
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creator Mao, Jianxing
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description [Display omitted] •The mechanism of solute affected slip-CTB interaction is investigated.•New metric to trigger the critical slip-CTB event is proposed based on MD simulation.•Continuum model for solution strengthening on slip-CTB interaction is established.•Criterion to determine the route of reaction is proposed and validated by MD simulation. The slip-coherent twin boundary (CTB) interaction, which is one of the most important issues determining the strength and ductility of the face-centered cubic metals, is investigated by molecular dynamics (MD) simulations on a bi-crystal model of Ni with interstitial Cr and Fe in CTB. Two interaction types, i.e., absorption and transmission, are observed, with prominent dependence on both the type and fraction of the solute. The threshold shear stress triggering the slip-CTB reaction event is quantitatively evaluated, and based on the local lattice friction, a new interpretation of the mechanism for solute affected slip-CTB interaction is proposed. A continuum model for solution affected slip-CTB interaction is established from a discrete dislocation scenario, including modified formulations in terms of the balanced condition of stress acting on the leading partial and elevated lattice friction, where the solute effect is effectively accounted and incorporated. Accordingly, the criterion to determine the nature of slip-CTB reaction is proposed, yielding good prediction of the critical events observed in MD simulations. This paper provides critical understanding and predictive tools for solute affected slip-CTB interaction in Ni, and offers new insights into alloy and microstructure engineering of Ni based superalloys with improved mechanical properties.
doi_str_mv 10.1016/j.commatsci.2021.110430
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The slip-coherent twin boundary (CTB) interaction, which is one of the most important issues determining the strength and ductility of the face-centered cubic metals, is investigated by molecular dynamics (MD) simulations on a bi-crystal model of Ni with interstitial Cr and Fe in CTB. Two interaction types, i.e., absorption and transmission, are observed, with prominent dependence on both the type and fraction of the solute. The threshold shear stress triggering the slip-CTB reaction event is quantitatively evaluated, and based on the local lattice friction, a new interpretation of the mechanism for solute affected slip-CTB interaction is proposed. A continuum model for solution affected slip-CTB interaction is established from a discrete dislocation scenario, including modified formulations in terms of the balanced condition of stress acting on the leading partial and elevated lattice friction, where the solute effect is effectively accounted and incorporated. Accordingly, the criterion to determine the nature of slip-CTB reaction is proposed, yielding good prediction of the critical events observed in MD simulations. 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The slip-coherent twin boundary (CTB) interaction, which is one of the most important issues determining the strength and ductility of the face-centered cubic metals, is investigated by molecular dynamics (MD) simulations on a bi-crystal model of Ni with interstitial Cr and Fe in CTB. Two interaction types, i.e., absorption and transmission, are observed, with prominent dependence on both the type and fraction of the solute. The threshold shear stress triggering the slip-CTB reaction event is quantitatively evaluated, and based on the local lattice friction, a new interpretation of the mechanism for solute affected slip-CTB interaction is proposed. A continuum model for solution affected slip-CTB interaction is established from a discrete dislocation scenario, including modified formulations in terms of the balanced condition of stress acting on the leading partial and elevated lattice friction, where the solute effect is effectively accounted and incorporated. Accordingly, the criterion to determine the nature of slip-CTB reaction is proposed, yielding good prediction of the critical events observed in MD simulations. 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The slip-coherent twin boundary (CTB) interaction, which is one of the most important issues determining the strength and ductility of the face-centered cubic metals, is investigated by molecular dynamics (MD) simulations on a bi-crystal model of Ni with interstitial Cr and Fe in CTB. Two interaction types, i.e., absorption and transmission, are observed, with prominent dependence on both the type and fraction of the solute. The threshold shear stress triggering the slip-CTB reaction event is quantitatively evaluated, and based on the local lattice friction, a new interpretation of the mechanism for solute affected slip-CTB interaction is proposed. A continuum model for solution affected slip-CTB interaction is established from a discrete dislocation scenario, including modified formulations in terms of the balanced condition of stress acting on the leading partial and elevated lattice friction, where the solute effect is effectively accounted and incorporated. 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subjects MD simulation
Ni based superalloy
Slip-CTB interaction
Solution strengthening
title Atomistic study and continuum modeling of solute strengthening in slip-CTB interaction
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