Stacking Fault Energy, Dislocation Density, and Twin Fault Probability Determined by Neutron Diffraction Peak Profile Analysis in CrCoNi Based Medium Entropy Alloys

Wanchuck Woo,Stefanus Harjo,Takuro Kawasaki,Jae-Suk Jeong,Muhammad Naeem,Xun-Li Wang,Haiyan He

doi:10.2139/ssrn.3474464

Stacking Fault Energy, Dislocation Density, and Twin Fault Probability Determined by Neutron Diffraction Peak Profile Analysis in CrCoNi Based Medium Entropy Alloys

Wanchuck Woo, Stefanus Harjo + Show 5 more

https://doi.org/10.2139/ssrn.3474464

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Journal: SSRN

Publication Date: Jan 1, 2019

Affiliation: Korea Atomic Energy Research Institute, Japan Atomic Energy Agency, Japan Proton Accelerator Research Complex, National Institute for Materials Science, Doosan Heavy Industries & Construction (South Korea), Materials Technology (United Kingdom), City University of Hong Kong, Chinese University of Hong Kong, Shenzhen, City University of Hong Kong, Shenzhen Research Institute

#Twin Fault Probability #Medium Entropy Alloys + Show 8 more

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Abstract

Neutron diffraction peak profile analysis was used to determine stacking fault energy (SFE), dislocation density, and twin fault probability (Ptw) in CrCoNi and CrCoNiFe medium entropy alloys at 293K and 140K. The CrCoNi shows higher Ptw (up to 3.8%) and dislocation density (up to 9.7 x 1015 m-2) than CrCoNiFe (1.3% and 3.4 x 1015 m-2, respectively) at 293K. Meanwhile, at 140K, the Ptw in CrCoNiFe increases significantly to 4.4%. The dominant twinning deformation is due to the lower SFEs of CrCoNi (16.1 mJ/m2) at 293K and CrCoNiFe (7.4 mJ/m2) at 140K compared to 32.1 mJ/m2 for CrCoNiFe at 293K.

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