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Study of superplastic deformation mechanisms using atomistic simulation approach
N. Chandra
, P. Dang
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peer-review
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Dive into the research topics of 'Study of superplastic deformation mechanisms using atomistic simulation approach'. Together they form a unique fingerprint.
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Keyphrases
Atomistic Simulation
100%
Deformation Mechanism
100%
Superplastic Deformation
100%
Simulation Approach
100%
Grain Boundary Sliding
100%
Energy Barrier
66%
Grain Boundary
66%
Free Surface
33%
Loading Conditions
33%
Shear Stress
33%
Symmetric Tilt Grain Boundary
33%
Equilibrium Configuration
33%
Grain Boundary Migration
33%
Grain Boundary Structure
33%
Sliding Process
33%
Shear Loading
33%
Engineering
Atomistic Simulation
100%
Superplastic Deformation
100%
Grain Boundary
100%
Deformation Mechanism
100%
Grain Boundary Sliding
75%
Energy Engineering
50%
Energy Barrier
50%
Free Surface
25%
Loading Condition
25%
Equilibrium Configuration
25%
Applied Shear Stress
25%
Material Science
Grain Boundary
100%
Deformation Mechanism
100%
Grain Boundary Sliding
75%
Aluminum
50%