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Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy

The tensile creep behavior of an equiatomic CoCrFeNiMn high-entropy alloy was systematically investigated over an intermediate temperature range (500–600 °C) and applied stress (140–400 MPa). The alloy exhibited a stress-dependent transition from a low-stress region (LSR-region I) to a high-stress r...

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Autores principales: Cao, Chengming, Fu, Jianxin, Tong, Tongwei, Hao, Yuxiao, Gu, Ping, Hao, Hai, Peng, Liangming
Formato: Online Artículo Texto
Lenguaje:English
Publicado: MDPI 2018
Materias:
Acceso en línea:https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7512559/
https://www.ncbi.nlm.nih.gov/pubmed/33266684
http://dx.doi.org/10.3390/e20120960
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author Cao, Chengming
Fu, Jianxin
Tong, Tongwei
Hao, Yuxiao
Gu, Ping
Hao, Hai
Peng, Liangming
author_facet Cao, Chengming
Fu, Jianxin
Tong, Tongwei
Hao, Yuxiao
Gu, Ping
Hao, Hai
Peng, Liangming
author_sort Cao, Chengming
collection PubMed
description The tensile creep behavior of an equiatomic CoCrFeNiMn high-entropy alloy was systematically investigated over an intermediate temperature range (500–600 °C) and applied stress (140–400 MPa). The alloy exhibited a stress-dependent transition from a low-stress region (LSR-region I) to a high-stress region (HSR-region II). The LSR was characterized by a stress exponent of 5 to 6 and an average activation energy of 268 kJ mol(−1), whereas the HSR showed much higher corresponding values of 8.9–14 and 380 kJ mol(−1). Microstructural examinations on the deformed samples revealed remarkable dynamic recrystallization at higher stress levels. Dislocation jogging and tangling configurations were frequently observed in LSR and HSR at 550 and 600 °C, respectively. Moreover, dynamic precipitates identified as M(23)C(6) or a Cr-rich σ phase were formed along grain boundaries in HSR. The diffusion-compensated strain rate versus modulus-compensated stress data analysis implied that the creep deformation in both stress regions was dominated by stress-assisted dislocation climb controlled by lattice diffusion. Nevertheless, the abnormally high stress exponents in HSR were ascribed to the coordinative contributions of dynamic recrystallization and dynamic precipitation. Simultaneously, the barriers imposed by these precipitates and severe initial deformation were referred to so as to increase the activation energy for creep deformation.
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spelling pubmed-75125592020-11-09 Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy Cao, Chengming Fu, Jianxin Tong, Tongwei Hao, Yuxiao Gu, Ping Hao, Hai Peng, Liangming Entropy (Basel) Article The tensile creep behavior of an equiatomic CoCrFeNiMn high-entropy alloy was systematically investigated over an intermediate temperature range (500–600 °C) and applied stress (140–400 MPa). The alloy exhibited a stress-dependent transition from a low-stress region (LSR-region I) to a high-stress region (HSR-region II). The LSR was characterized by a stress exponent of 5 to 6 and an average activation energy of 268 kJ mol(−1), whereas the HSR showed much higher corresponding values of 8.9–14 and 380 kJ mol(−1). Microstructural examinations on the deformed samples revealed remarkable dynamic recrystallization at higher stress levels. Dislocation jogging and tangling configurations were frequently observed in LSR and HSR at 550 and 600 °C, respectively. Moreover, dynamic precipitates identified as M(23)C(6) or a Cr-rich σ phase were formed along grain boundaries in HSR. The diffusion-compensated strain rate versus modulus-compensated stress data analysis implied that the creep deformation in both stress regions was dominated by stress-assisted dislocation climb controlled by lattice diffusion. Nevertheless, the abnormally high stress exponents in HSR were ascribed to the coordinative contributions of dynamic recrystallization and dynamic precipitation. Simultaneously, the barriers imposed by these precipitates and severe initial deformation were referred to so as to increase the activation energy for creep deformation. MDPI 2018-12-12 /pmc/articles/PMC7512559/ /pubmed/33266684 http://dx.doi.org/10.3390/e20120960 Text en © 2018 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).
spellingShingle Article
Cao, Chengming
Fu, Jianxin
Tong, Tongwei
Hao, Yuxiao
Gu, Ping
Hao, Hai
Peng, Liangming
Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title_full Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title_fullStr Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title_full_unstemmed Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title_short Intermediate-Temperature Creep Deformation and Microstructural Evolution of an Equiatomic FCC-Structured CoCrFeNiMn High-Entropy Alloy
title_sort intermediate-temperature creep deformation and microstructural evolution of an equiatomic fcc-structured cocrfenimn high-entropy alloy
topic Article
url https://www.ncbi.nlm.nih.gov/pmc/articles/PMC7512559/
https://www.ncbi.nlm.nih.gov/pubmed/33266684
http://dx.doi.org/10.3390/e20120960
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