Engineering
Compression Strength
100%
Composite Material
100%
Compressive Strength
100%
Energy dispersive spectrometry
100%
Wear Resistance
100%
Ray Diffraction
100%
Friction Coefficient
100%
Energy Engineering
100%
Corrosion Behavior
100%
Signal-to-Noise Ratio
100%
Tribology
100%
Powder Metallurgy Method
100%
Applied Load
100%
Resistance Property
100%
Coefficient of Friction
100%
Taguchi Method
100%
Material Science
Matrix Composite
100%
Energy-Dispersive X-Ray Spectroscopy
100%
Magnesium
100%
Surface Analysis
50%
Powder Metallurgy
50%
Corrosion
50%
Scanning Electron Microscopy
50%
Coefficient of Friction
50%
Compressive Strength
50%
Scanning Electron Microscopy-Energy Dispersive X-Ray
50%
Magnesium Alloy
50%
Density
50%
Magnesium Alloys
50%
Strength of Materials
50%
Taguchi Method
50%
Wear Resistance
50%
Tribology
50%
Signal-to-Noise Ratio
50%
Composite Material
50%
X-Ray Diffraction
50%
Reinforced Composite
50%
Keyphrases
Hydroxyapatite
100%
Magnesium Matrix Composites
100%
Microstructure Properties
100%
Mechanical Properties
100%
Wear Rate
33%
Reinforced
33%
Composite Sample
16%
Friction Coefficient
16%
Weight Percentage
16%
Friction
16%
Wear Resistance Property
16%
Corrosion Behavior
16%
Microstructural Study
16%
Mechanical Strength
16%
Magnesium Alloy
16%
Wear Behavior
16%
Optimum Parameters
16%
Compressive Strength
16%
Taguchi Method
16%
Scanning Electron Microscopy
16%
Mg Alloy
16%
Signal-to-noise Ratio Analysis
16%
Scanning Electron Microscopy/energy Dispersive Spectroscopy
16%
Corrosive Wear
16%
Applied Load
16%
Composite Materials
16%
Tribology
16%
Worn Surface Analysis
16%
Microstructure
16%
Hydroxyapatite Composite
16%
Powder Metallurgy Method
16%
Uniform Distribution
16%
X Ray Diffraction
16%