Engineering
Anisotropic
50%
Bayesian Model
100%
Classification Method
50%
Crystal Plasticity Model
50%
Fatigue Crack Nucleation
100%
Fatigue Loading
50%
Finite Element Modeling
50%
Learning Approach
50%
Microstructure
50%
Multiscale Model
50%
Nucleation Site
100%
Plasticity Model
50%
Polycrystalline
50%
Representative Volume Element
100%
State Variable
100%
Keyphrases
Anisotropic Continua
16%
Bayesian Classification
16%
Bayesian Inference
16%
Bayesian Modeling
100%
Concurrent multiscale Model
16%
Continuum Plasticity
16%
Crack Location
16%
Crack nucleation
100%
Crystal Plasticity
16%
Crystal Plasticity Finite Element Method (CPFEM)
16%
Data-driven Machine Learning
16%
Diffraction Image
16%
Electron Backscatter Diffraction
16%
Exterior Domain
16%
Fatigue Crack nucleation
100%
Fatigue Load
16%
Fatigue Simulation
16%
Grain Morphology
16%
Machine Learning Approach
16%
Microstructural
16%
Microstructure
16%
Model Embedding
16%
Model Prediction
100%
Ni-based Superalloy
100%
Nucleation Model
16%
Nucleation Site
33%
Plasticity Model
16%
Representative Volume Element
33%
Scalar
16%
Scanning Electron Microscopy
16%
Material Science
Crystal Plasticity
28%
Crystallography
14%
Electron Backscatter Diffraction
14%
Fatigue Crack
100%
Finite Element Modeling
14%
Homogenization
14%
Nickel-Based Superalloys
100%
Nucleation
100%
Scanning Electron Microscopy
14%