Engineering
Crack Tip
95%
Crack Growth
91%
Fatigue Crack Growth
84%
Cracking Behavior
50%
Fatigue Crack
50%
Retardation
49%
Plastic Zone
43%
Scanning Electron Microscope
38%
Perfluorosulfonic Acid
38%
Elevated Temperature
33%
High Cycle Fatigue
33%
Strain Field
33%
Microstructure
30%
Schmids Factor
30%
Load Cycle
25%
Mechanical Fatigue Test
25%
Crack Closure
23%
Stress Ratio
22%
Continuous Variation
21%
Crack Growth Behavior
21%
Crack Tip Opening Displacement
16%
Experimental Investigation
16%
Growth Mechanism
16%
Selective Laser Melting
16%
Small Crack
16%
Carburized Steel
16%
Fatigue Crack Propagation
16%
Failure Strength
16%
Induced Cracking
16%
Numerical Study
16%
Fatigue Failure
16%
Multiscale
16%
Failure Behavior
16%
Blade Turbine
16%
Applied Load
16%
Protonation
16%
Proton Exchange Membrane
16%
Crack Growth Rate
15%
High Resolution
14%
Load Test
14%
Crack Front
14%
Plastic Deformation
14%
Resolution Image
14%
Edge Crack
14%
Fracture Surface
14%
Tensiles
14%
Constitutive Relationship
14%
Micro Crack
12%
Microcracks
12%
Finite Element Method
12%
Material Science
Crack Growth
100%
Fatigue Crack Growth
85%
High-Cycle Fatigue
67%
Nickel-Based Superalloys
67%
Crack Tip
61%
Scanning Electron Microscopy
50%
Fatigue Crack
38%
Titanium Alloys
33%
Nucleation
30%
Mechanical Strength
29%
Fatigue of Materials
28%
Electron Backscatter Diffraction
22%
Mechanical Property
21%
Plastic Deformation
19%
Crack Tip Opening Displacement
16%
Small Crack
16%
Selective Laser Melting
16%
Constitutive Modeling
16%
Elastic Moduli
16%
Strain Rate
16%
Tensile Property
16%
Battery (Electrochemical Energy Engineering)
16%
Yield Stress
16%
Stress Relaxation
16%
Finite Element Method
12%
Microcracks
12%
Residual Stress
9%
Stress Concentration
8%
Focused Ion Beam
8%
Oxide Compound
8%
Grain Boundary
8%
Method in Fracture Mechanics
8%
Activation Energy
8%
Crack Initiation
8%
Crack Propagation
8%
Crack Closure
7%
Carburization
5%
Microstructure Characterization
5%