Biodegradation-affected fatigue behavior of additively manufactured porous magnesium

INIS

• magnesium 100%
• porous materials 100%
• fatigue 100%
• biodegradation 100%
• loading 55%
• lasers 33%
• cracks 33%
• melting 22%
• microstructure 22%
• performance 22%
• electrons 11%
• design 11%
• diffraction 11%
• air 11%
• finite element method 11%
• pits 11%
• units 11%
• junctions 11%
• dislocations 11%
• diamonds 11%
• simulation 11%
• alloys 11%
• processing 11%
• metals 11%
• body fluids 11%
• optimization 11%
• interactions 11%
• transmission electron microscopy 11%
• information 11%
• biological materials 11%
• comparative evaluations 11%
• yield strength 11%
• x-ray diffraction 11%
• topology 11%
• concentration 11%
• magnesium alloys 11%
• bones 11%

Material Science

• Biodegradation 100%
• Magnesium 100%
• Fatigue Behavior 100%
• Crack 33%
• Porous Material 33%
• Microstructure 22%
• Selective Laser Melting 22%
• Diamond 11%
• Finite Element Method 11%
• Mechanical Strength 11%
• Laser Processing 11%
• Electron Backscatter Diffraction 11%
• Dislocation 11%
• Air 11%
• Yield Stress 11%
• Stress Concentration 11%
• Magnesium Alloys 11%
• Biomaterial 11%
• Metal 11%
• Bone Substitutes 11%
• X-Ray Diffraction 11%
• Ultimate Tensile Strength 11%
• Scanning Transmission Electron Microscopy 11%

Engineering

• We43 Alloy 11%
• Porous Mg Alloy 11%