Keyphrases
Laser Therapy
100%
Fatigue Resistance
100%
Strength-ductility Synergy
100%
Mg Alloy
100%
Laser Surface Processing
100%
Remelted Layer
75%
Average Grain Size
25%
Microcracks
25%
Microscope Observation
25%
Fatigue Life
25%
Yield Strength
25%
Laser Processing
25%
Laser Surface Melting
25%
Equiaxed
25%
Undercooling
25%
Nanostructures
25%
High Hardness
25%
Engineering Environment
25%
Ultimate Tensile Strength
25%
Practical Engineering
25%
Processing Parameters
25%
Service Performance
25%
Remelting
25%
High Cooling Rate
25%
Rate-based
25%
Microstructural Evolution
25%
Fatigue Limit
25%
Good Ductility
25%
Grain Refinement
25%
In Situ Transmission Electron Microscope
25%
Conventional Laser
25%
Solute Element
25%
Low Duty Cycle
25%
Precipitation Distribution
25%
Synergistic Strengthening
25%
Morphological Distribution
25%
Grain Morphology
25%
Constitutional Supercooling
25%
Liquid Nitrogen Cooling
25%
Strain Hardening Capacity
25%
Heterogeneous Layer
25%
Surface Remelting Treatment
25%
Mg17Al12 Precipitation
25%
Optimized Processing
25%
Gradient Grain
25%
High Cycle Fatigue Test
25%
Additive Manufacturing Application
25%
Engineering
Surface Processing
100%
Fatigue Resistance
100%
Laser Surface
100%
Original Sample
100%
Additive Manufacturing
50%
Mechanical Fatigue Test
50%
Strengthening Mechanism
50%
Average Grain Size
50%
Processing Parameter
50%
High Cycle Fatigue
50%
Critical Application
50%
Service Performance
50%
Laser Processing
50%
Engineering
50%
High Cooling Rate
50%
Constitutional Supercooling
50%
Fatigue Lifetime
50%
Ultimate Tensile Strength
50%
Microstructural Evolution
50%
Fatigue Limit
50%
Strain Hardening
50%
Yield Point
50%
Remelting
50%
Material Science
Fatigue of Materials
100%
Magnesium Alloys
100%
Surface (Surface Science)
100%
Strength Ductility Synergy
100%
Three Dimensional Printing
33%
Work Hardening
33%
Microstructural Evolution
33%
Grain Refinement
33%
Yield Stress
33%
Grain Size
33%
High-Cycle Fatigue
33%
Ultimate Tensile Strength
33%