Achieving exceptional work-hardening capability of additively-manufactured multiphase Fe-Mn alloys via multiple deformation mechanisms

Keyphrases

• Deformation Mechanism 100%
• Work Hardening Rate 100%
• Additive Manufacturing 100%
• Fe-Mn Alloy 100%
• Multiple Deformation 100%
• Tensile Strength 40%
• FeMn 40%
• Fe-based 40%
• Deformation Twinning 40%
• Laser Powder Bed Fusion (L-PBF) 40%
• Annealing 20%
• Grain Size 20%
• Dislocation Density 20%
• High Density 20%
• Stacking Fault Energy 20%
• Nanometre 20%
• Martensitic Transformation 20%
• Premature Failure 20%
• Degradation Rate 20%
• Ferrite 20%
• Hard Phase 20%
• Orthopedic Applications 20%
• Planar Defects 20%
• Martensite 20%
• Heterogeneous Microstructure 20%
• Mn-Fe 20%
• Soft Phase 20%
• Uniform Microstructure 20%
• Bone Substitutes 20%
• Fracture Elongation 20%
• High-entropy Alloy 20%
• Martensite-austenite Constituent 20%
• Biodegradable Alloys 20%
• Cooperative Deformation 20%
• Multiphase Materials 20%
• Fusion Processing 20%
• Excess Gibbs Free Energy 20%
• Mn Steel 20%
• Pre-alloyed Powder 20%
• Martensite Microstructure 20%

Engineering

• Deformation Mechanism 100%
• Strain Hardening 100%
• Martensite 60%
• Deformation Twin 40%
• Ultimate Tensile Strength 40%
• Laser Powder Bed Fusion 40%
• Nanometre 20%
• High-Entropy Alloys 20%
• Premature Failure 20%
• Orthopedic Application 20%
• Soft Phase 20%
• Hard Phase 20%
• Fracture Elongation 20%
• Austenite 20%
• Bone Substitutes 20%
• Stacking Fault Energy 20%
• Mn Steel 20%
• Gibbs Free Energy 20%
• Degradation Rate 20%

Material Science

• Work Hardening 100%
• Deformation Mechanism 100%
• Martensite 60%
• Ultimate Tensile Strength 40%
• Laser Powder Bed Fusion 40%
• Grain Size 20%
• Austenite 20%
• Density 20%
• High Entropy Alloys 20%
• Bone Substitutes 20%
• Crystal Defect 20%