The creep deformation mechanisms of a newly designed nickel-base superalloy

The influences of applied stress (120–760MPa) and temperature (700–1000°C) on the creep deformation mechanisms of the newly developed nickel-base superalloy M951G have been studied. The dominant deformation mechanisms of M951G alloy after different creep tests were systematically investigated and th...

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Bibliographic Details
Published in:Materials science & engineering. A, Structural materials : properties, microstructure and processing Structural materials : properties, microstructure and processing, 2018-01, Vol.710, p.309-317
Main Authors: Cui, Luqing, Yu, Jinjiang, Liu, Jinlai, Jin, Tao, Sun, Xiaofeng
Format: Article
Language:English
Subjects:
Antiphase boundaries
Chemical precipitation
Continuous stacking fault
Creep behavior
Creep strength
Creep tests
Critical resolved shear stress
Crystal defects
Deformation
Deformation mechanisms
Dislocation mobility
Favorable deformation mechanism
M951G alloy
Nickel base alloys
Precipitates
Shear stress
Shearing
Superalloys
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Summary:The influences of applied stress (120–760MPa) and temperature (700–1000°C) on the creep deformation mechanisms of the newly developed nickel-base superalloy M951G have been studied. The dominant deformation mechanisms of M951G alloy after different creep tests were systematically investigated and the reasons for their transition were well discussed. A creep mechanism map at various creep conditions was summarized and the theoretical critical resolved shear stresses (CRSSs) of various creep mechanisms under different temperatures were also calculated. Results show that the CRSSs of different creep mechanisms display different dependencies of temperature and the favorable deformation mechanisms at different creep conditions are different. τAPB, τOB and τCL are decreased to varying degrees with the temperature increasing; on the contrary, there is a positive correlation between τSF and temperature. At low temperature region, the favorable deformation mechanism is shearing of γ′ precipitates by stacking faults. However, it changes to antiphase boundaries (APBs) coupled dislocation pairs shearing in the γ′ precipitates and dislocation climbing in the γ matrix channel at high temperatures. At intermediate temperatures, both stacking faults and APBs are observed owing to the alternate leading of the CRSSs for APBs and stacking faults shearing in γ′ precipitates.
ISSN:0921-5093
1873-4936
DOI:10.1016/j.msea.2017.11.002