Nanoindentation size effects of mechanical and creep performance in Ni-based superalloy

Nanoindentation technique was adopted to study indentation size effects of physical-mechanical and creep performance with various depths (200-2000 nm) in GH901 utilising sharp and spherical tip. Residual impressions of both indenters with pile-up patterns are discussed. Nanohardness, reduced modulus...

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Published inMaterials science and technology Vol. 39; no. 12; pp. 1543 - 1554
Main Authors Huang, Yanyan, Zhou, Cheng, Chen, Keyan, Yang, Yuxin, Xiong, Jiankun, Yang, Jianping, Guo, Yang, Mao, Guijun, Yang, Lin, Nie, Fuheng, Li, Xia, Zhou, Qinghua
Format Journal Article
LanguageEnglish
Published London, England Taylor & Francis 13.08.2023
SAGE Publications
Subjects
creep performance
indentation size effect
Nanoindentation
Ni-based superalloy
physical and mechanical properties
creep performance
indentation size effect
Ni-based superalloy
Nanoindentation
physical and mechanical properties
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Abstract Nanoindentation technique was adopted to study indentation size effects of physical-mechanical and creep performance with various depths (200-2000 nm) in GH901 utilising sharp and spherical tip. Residual impressions of both indenters with pile-up patterns are discussed. Nanohardness, reduced modulus and elastic recovery rates curves versus maximum displacement of two tips are obtained and nanohardness size effects are discussed with different models for Berkovich tip. The data obtained with spherical indentation are analysed separately by establishing stress-strain diagram. The creep results using Berkovich tip indicate that creep strain rate declines while creep stress exponent first decreases and then increases with the increasing depth; the creep stress exponent (n) values, 2.39-7.35, imply the dominant creep deformation mechanism is dislocation control.
AbstractList Nanoindentation technique was adopted to study indentation size effects of physical-mechanical and creep performance with various depths (200-2000 nm) in GH901 utilising sharp and spherical tip. Residual impressions of both indenters with pile-up patterns are discussed. Nanohardness, reduced modulus and elastic recovery rates curves versus maximum displacement of two tips are obtained and nanohardness size effects are discussed with different models for Berkovich tip. The data obtained with spherical indentation are analysed separately by establishing stress-strain diagram. The creep results using Berkovich tip indicate that creep strain rate declines while creep stress exponent first decreases and then increases with the increasing depth; the creep stress exponent (n) values, 2.39-7.35, imply the dominant creep deformation mechanism is dislocation control.
Author Zhou, Cheng
Yang, Lin
Chen, Keyan
Yang, Jianping
Mao, Guijun
Zhou, Qinghua
Guo, Yang
Yang, Yuxin
Xiong, Jiankun
Li, Xia
Nie, Fuheng
Huang, Yanyan
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Issue 12
Keywords creep performance
indentation size effect
Ni-based superalloy
Nanoindentation
physical and mechanical properties
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Snippet Nanoindentation technique was adopted to study indentation size effects of physical-mechanical and creep performance with various depths (200-2000 nm) in GH901...
Nanoindentation technique was adopted to study indentation size effects of physical-mechanical and creep performance with various depths (200–2000 nm) in GH901...
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SubjectTerms creep performance
indentation size effect
Nanoindentation
Ni-based superalloy
physical and mechanical properties
Title Nanoindentation size effects of mechanical and creep performance in Ni-based superalloy
URI https://www.tandfonline.com/doi/abs/10.1080/02670836.2023.2173898
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