Keyphrases
Physics-based
100%
Laser Powder Bed Fusion (L-PBF)
100%
Microstructure Evolution
100%
Ti-6Al-4V (Ti64)
100%
Part-scale
100%
Microstructural Model
100%
Selective Laser Melting
66%
Martensite
66%
Transformation Criteria
66%
Identification Process
33%
Parameter-free
33%
Numerical Results
33%
Temperature Profile
33%
Diffusion-based
33%
Stable Phase
33%
Microstructure
33%
High Cooling Rate
33%
Microstructural
33%
Minimal number
33%
Failure Mode
33%
Surface Domains
33%
Strength of Materials
33%
Predictive Ability
33%
Evolution Equations
33%
Time-dependent Diffusion Coefficient
33%
Temperature Field
33%
Quenching Process
33%
Base Plate
33%
Coexisting Phases
33%
Sigma Phase
33%
Material Failure
33%
Phase Fraction
33%
Arbitrary Temperatures
33%
Inverse Identification
33%
Temperature-dependent Diffusion Coefficients
33%
Critical Cooling Rate
33%
Continuous Cooling Transformation Diagram
33%
Diffusional Transformation
33%
Time-temperature-transformation Diagram
33%
Additive Technologies
33%
Metastable Phases
33%
Elastoplastic Material Behaviour
33%
Localized Heat Source
33%
Engineering
Powder Bed Fusion
100%
Microstructure Evolution
100%
Ti-6al-4v
100%
Selective Laser Melting
66%
Martensite
66%
Free Parameter
33%
Additive Manufacturing Technology
33%
High Cooling Rate
33%
Experimental Observation
33%
Material Behavior
33%
Temperature Time
33%
Baseplate
33%
Stable Phase
33%
Domain Surface
33%
Fusion Process
33%
Minimal Number
33%
Phase Fraction
33%
Critical Cooling Rate
33%
Predictive Ability
33%
Failure Mode
33%
Diffusion Coefficient
33%
Metastable Phase
33%
Temperature Distribution
33%
Actuator
33%
Heat Sources
33%
Temperature Profile
33%
Material Science
Laser Powder Bed Fusion
100%
Ti-6Al-4V
100%
Selective Laser Melting
66%
Martensite
66%
Three Dimensional Printing
33%
Diffusivity
33%
Plastic Material
33%
Surface (Surface Science)
33%
Strength of Materials
33%