Effects of plasma electrolytic oxidation process on the mechanical properties of additively manufactured porous biomaterials

INIS

• oxidation 100%
• porous materials 100%
• plasma 100%
• biological materials 100%
• mechanical properties 100%
• surfaces 37%
• scanning electron microscopy 25%
• layers 25%
• density 25%
• fatigue 25%
• yields 25%
• loading 25%
• mechanical tests 12%
• dynamics 12%
• energy absorption 12%
• compression 12%
• manufacturing 12%
• host 12%
• energy 12%
• units 12%
• values 12%
• alloys 12%
• thickness 12%
• optical microscopy 12%
• oxides 12%
• interactions 12%
• modifications 12%
• tissues 12%
• comparative evaluations 12%
• titanium 12%
• images 12%
• x-ray spectroscopy 12%
• additives 12%

Engineering

• Mechanical Properties 100%
• Scaffold 100%
• Relative Density 50%
• Yield Stress 50%
• Conventional Technique 25%
• Complex Structure 25%
• Porous Structure 25%
• Metallic Biomaterials 25%
• Oxide Layer 25%
• Additive Manufacturing Technique 25%
• Fatigue Loading 25%
• Manufactured Ti6al4v 25%
• Loading Cycle 25%
• Images 25%
• Mechanical Testing 25%
• Dynamic Fatigue 25%
• Energy Absorption 25%
• Test Result 25%
• Maximum Stress 25%
• Functional Layer 25%
• Young's Modulus 25%
• Energy Engineering 25%

Material Science

• Biomaterial 100%
• Oxidation Reaction 100%
• Density 25%
• Yield Stress 25%
• Energy-Dispersive X-Ray Spectroscopy 25%
• Scanning Electron Microscopy 12%
• Microscopy 12%
• Three Dimensional Printing 12%
• Scanning Electron Microscopy-Energy Dispersive X-Ray 12%
• Oxide Compound 12%
• Surface Treatment 12%
• Elastic Moduli 12%
• Mechanical Testing 12%
• Metallic Biomaterial 12%
• Titanium 12%
• Functional Surface 12%