Keyphrases
Aluminum Matrix Composites
100%
Ti3SiC2
100%
Particle Reinforcement
100%
MAX Phase
80%
Metal Matrix Composites
60%
Reinforced
40%
Low Temperature
20%
Coarse Particles
20%
Electrical Conductivity
20%
Mapping Analysis
20%
Mechanical Properties
20%
Advanced Materials
20%
Porosity
20%
Thermal Conductivity
20%
Fracture Toughness
20%
Metal Matrix
20%
Thin Oxides
20%
Grain Boundary
20%
Wear Resistance
20%
Fine Particles
20%
Layered Structure
20%
Weak Interface
20%
High Mechanical Strength
20%
Ceramic Particles
20%
Microstructural Analysis
20%
Superior Mechanical Properties
20%
Homogeneous Microstructure
20%
Al Composites
20%
Nanoindentation Hardness
20%
Spark Plasma Sintering
20%
Sintering Process
20%
Residual Porosity
20%
Strengthening Mechanism
20%
Traditional Ceramics
20%
High Bending Strength
20%
Hardness Mapping
20%
Machinability
20%
Material Science
Aluminum
100%
Matrix Composite
100%
Particle-Reinforcement
100%
MAX Phases
100%
Metal Matrix Composite
75%
Oxide Compound
25%
Electrical Conductivity
25%
Mechanical Strength
25%
Flexural Strength
25%
Advanced Material
25%
Thermal Conductivity
25%
Microstructural Analysis
25%
Fracture Toughness
25%
Sintering
25%
Grain Boundary
25%
Nanoindentation
25%
Wear Resistance
25%
Fine Particle
25%
Spark Plasma Sintering
25%
Machinability
25%
Engineering
Metal Matrix Composite
100%
Aluminum Matrix
100%
Microstructure
33%
Low-Temperature
33%
Electrical Conductivity
33%
Anisotropic
33%
Porosity
33%
Thermal Conductivity
33%
Impact Toughness
33%
Oxide Layer
33%
Grain Boundary
33%
Wear Resistance
33%
Bending Strength
33%
Phase Particle
33%
Layered Structure
33%
Coarse Particle
33%
Spark Plasma Sintering
33%
Sintering Process
33%
Residual Porosity
33%
Ceramic Particle
33%
Strengthening Mechanism
33%