Deciphering non-elastic deformation in amorphous alloy: Simultaneous aging-induced ordering and rejuvenation-induced disordering

Q. Hao; G. J. Lyu; E. Pineda; J. M. Pelletier; Y. J. Wang; Y. Yang; J. C. Qiao

doi:10.1016/j.ijplas.2024.103926

Deciphering non-elastic deformation in amorphous alloy: Simultaneous aging-induced ordering and rejuvenation-induced disordering

Q. Hao, G. J. Lyu^*, E. Pineda, J. M. Pelletier, Y. J. Wang, Y. Yang, J. C. Qiao^*

^*Corresponding author for this work

Research output: Journal Publications and Reviews › RGC 21 - Publication in refereed journal › peer-review

13 Citations (Scopus)

Abstract

The mechanical and physical properties of amorphous alloys depend on their time, temperature, and stress history. Due to their out-of-thermodynamic-equilibrium nature, describing the nonelastic deformation while considering the evolution of the structural state poses a significant challenge. We address this challenge by incorporating a parameter for structural state changes into a conventional deformation theory. This allows us to account for aging-induced ordering and deformation-induced disordering in the description of the mechanical deformation. In the apparent elastic regime (small strain), aging dominates while disorder caused by deformation can be disregarded. In this context, we have also made modifications to the widely used stretched exponential function, incorporating in-situ aging during deformation. This modification successfully describes the stress relaxation behavior under small deformation conditions and provides insights into parameter evolution in this process. Under large deformation conditions, both aging and deformation induced rejuvenation effects on the structural state must be considered simultaneously. By analyzing the evolution of defect concentration during this process, we describe relevant experimental results within the framework of the free volume theory, effectively separating the contributions of aging and rejuvenation to the structural state during the deformation process. © 2024 Elsevier Ltd

Original language	English
Article number	103926
Journal	International Journal of Plasticity
Volume	175
Online published	27 Feb 2024
DOIs	https://doi.org/10.1016/j.ijplas.2024.103926
Publication status	Published - Apr 2024

Funding

This work is supported by the NSFC (Grant Nos. 51971178 and 52271153 ) and the Natural Science Basic Research Plan for Distinguished Young Scholars in Shaanxi Province (Grant No. 2021JC-12 ). YJW was financially supported by NSFC (Grant No. 12072344 ) and the Youth Innovation Promotion Association of the Chinese Academy of Sciences. YY acknowledges financial support from Research Grant Council (RGC), the Hong Kong government through the General Research Fund (GRF) with the grant numbers CityU11206362 and N_CityU 109/21 . E. P. acknowledge financial support from ‘Proyecto PID2020–112975GB-I00 de investigación financiado por MCIN/AEI /10.13039/501100011033′ and Generalitat de Catalunya, AGAUR grant 2021-SGR-00343 . Q. Hao is sponsored by the Innovation Foundation for Doctor Dissertation of Northwestern Polytechnical University (No. CX2023054 ).

Research Keywords

Amorphous alloy
Non-elastic deformation
Physical aging
Rejuvenation
Stress relaxation

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title = "Deciphering non-elastic deformation in amorphous alloy: Simultaneous aging-induced ordering and rejuvenation-induced disordering",

abstract = "The mechanical and physical properties of amorphous alloys depend on their time, temperature, and stress history. Due to their out-of-thermodynamic-equilibrium nature, describing the nonelastic deformation while considering the evolution of the structural state poses a significant challenge. We address this challenge by incorporating a parameter for structural state changes into a conventional deformation theory. This allows us to account for aging-induced ordering and deformation-induced disordering in the description of the mechanical deformation. In the apparent elastic regime (small strain), aging dominates while disorder caused by deformation can be disregarded. In this context, we have also made modifications to the widely used stretched exponential function, incorporating in-situ aging during deformation. This modification successfully describes the stress relaxation behavior under small deformation conditions and provides insights into parameter evolution in this process. Under large deformation conditions, both aging and deformation induced rejuvenation effects on the structural state must be considered simultaneously. By analyzing the evolution of defect concentration during this process, we describe relevant experimental results within the framework of the free volume theory, effectively separating the contributions of aging and rejuvenation to the structural state during the deformation process. {\textcopyright} 2024 Elsevier Ltd",

keywords = "Amorphous alloy, Non-elastic deformation, Physical aging, Rejuvenation, Stress relaxation",

author = "Q. Hao and Lyu, {G. J.} and E. Pineda and Pelletier, {J. M.} and Wang, {Y. J.} and Y. Yang and Qiao, {J. C.}",

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T2 - Simultaneous aging-induced ordering and rejuvenation-induced disordering

AU - Hao, Q.

AU - Lyu, G. J.

AU - Pineda, E.

AU - Pelletier, J. M.

AU - Wang, Y. J.

AU - Yang, Y.

AU - Qiao, J. C.

PY - 2024/4

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N2 - The mechanical and physical properties of amorphous alloys depend on their time, temperature, and stress history. Due to their out-of-thermodynamic-equilibrium nature, describing the nonelastic deformation while considering the evolution of the structural state poses a significant challenge. We address this challenge by incorporating a parameter for structural state changes into a conventional deformation theory. This allows us to account for aging-induced ordering and deformation-induced disordering in the description of the mechanical deformation. In the apparent elastic regime (small strain), aging dominates while disorder caused by deformation can be disregarded. In this context, we have also made modifications to the widely used stretched exponential function, incorporating in-situ aging during deformation. This modification successfully describes the stress relaxation behavior under small deformation conditions and provides insights into parameter evolution in this process. Under large deformation conditions, both aging and deformation induced rejuvenation effects on the structural state must be considered simultaneously. By analyzing the evolution of defect concentration during this process, we describe relevant experimental results within the framework of the free volume theory, effectively separating the contributions of aging and rejuvenation to the structural state during the deformation process. © 2024 Elsevier Ltd

AB - The mechanical and physical properties of amorphous alloys depend on their time, temperature, and stress history. Due to their out-of-thermodynamic-equilibrium nature, describing the nonelastic deformation while considering the evolution of the structural state poses a significant challenge. We address this challenge by incorporating a parameter for structural state changes into a conventional deformation theory. This allows us to account for aging-induced ordering and deformation-induced disordering in the description of the mechanical deformation. In the apparent elastic regime (small strain), aging dominates while disorder caused by deformation can be disregarded. In this context, we have also made modifications to the widely used stretched exponential function, incorporating in-situ aging during deformation. This modification successfully describes the stress relaxation behavior under small deformation conditions and provides insights into parameter evolution in this process. Under large deformation conditions, both aging and deformation induced rejuvenation effects on the structural state must be considered simultaneously. By analyzing the evolution of defect concentration during this process, we describe relevant experimental results within the framework of the free volume theory, effectively separating the contributions of aging and rejuvenation to the structural state during the deformation process. © 2024 Elsevier Ltd

KW - Amorphous alloy

KW - Non-elastic deformation

KW - Physical aging

KW - Rejuvenation

KW - Stress relaxation

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ER -

Deciphering non-elastic deformation in amorphous alloy: Simultaneous aging-induced ordering and rejuvenation-induced disordering

Abstract

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Research Keywords

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NSFC: Two-Dimensional (2D) Metallic Glasses: From Synthesis, Physical/Mechanical Properties to Alloy Design

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Deciphering non-elastic deformation in amorphous alloy: Simultaneous aging-induced ordering and rejuvenation-induced disordering

Abstract

Funding

Research Keywords

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Projects

NSFC: Two-Dimensional (2D) Metallic Glasses: From Synthesis, Physical/Mechanical Properties to Alloy Design

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