Material Science
Crystal Plasticity
100%
Finite Element Method
59%
Finite Element Modeling
51%
Magnesium Alloy
29%
Strain Rate
20%
Magnesium
19%
Nucleation
18%
Crack Propagation
14%
Three Dimensional Printing
14%
Indentation
12%
Nickel Alloy
11%
Grain Boundary
10%
Stress-Strain Relations
9%
Magnesium Alloys
8%
Plastic Deformation
8%
Actuator
8%
Volume Fraction
7%
Polycrystal
7%
Alloy Steel
7%
Surface Roughness
7%
Stainless Steel
6%
Deformation Mechanism
6%
Nickel-Based Superalloys
6%
Mechanical Property
6%
Intermetallics
6%
Yield Stress
5%
Morphology
5%
Fatigue Crack
5%
Bulk Metallic Glass
5%
Nanoindentation
5%
High-Cycle Fatigue
5%
Polyester
5%
Aluminum
5%
Silicon
5%
Tungsten
5%
Surface Engineering
5%
Probabilistic Model
5%
Thermomechanical Property
5%
Synchrotron X-Ray Diffraction
5%
Austenite
5%
Hydrogen Embrittlement
5%
Crack Initiation
5%
Scanning Electron Microscopy
5%
Solidification
5%
Inconel
5%
Neutron Diffraction
5%
Laser Powder Bed Fusion
5%
Composite Material
5%
Engineering
Polycrystalline
49%
Finite Element Modeling
37%
Finite Element Analysis
31%
Crystal Plasticity Model
27%
Finite Element Simulation
24%
Fem Model
18%
Strain Localization
17%
Stress-Strain Relations
15%
Crack Propagation
12%
Actuator
12%
Az31 Alloy
11%
Ultrasonic Welding
11%
Heat Generation
11%
Plastic Deformation
10%
Strain Rate
9%
Slip System
9%
Subdomains
9%
Powder Bed Fusion
9%
Finite Element Formulation
9%
Indentation
8%
Multiscale
8%
Premature Failure
8%
Mechanical Property
8%
Interlayer
8%
Nodes
8%
Room Temperature
8%
Abradable Coating
8%
Experimental Result
8%
Computational Efficiency
7%
Mesoscale
7%
Polycrystal
7%
High Resolution
7%
Energy Barrier
7%
Vaporization
7%
Alloy Steel
7%
Yield Point
6%
Hexagonal Close Packed
6%
Finite Element Mesh
6%
Applied Strain Rate
6%
Intermetallics
5%
Joints (Structural Components)
5%
Time Domain
5%
Shear Banding
5%
Engineering
5%
Tetrahedral Element
5%
Digital Image Correlation
5%
Fatigue Crack Propagation
5%
Phase Field
5%
Acceleration Method
5%
High Cycle Fatigue
5%