Journal
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING
Volume 857, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.msea.2022.144101
Keywords
Laser powder bed fusion (LPBF); Metal matrix composites (MMCs); Microstructural modulation; Mechanical properties; Wear properties
Categories
Funding
- China Scholarship Council [201806830109]
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This study demonstrates an in-situ microscale composition modulation method using laser powder bed fusion, achieving a balanced combination of mechanical and wear properties in metal composites. The modulation method creates a pathway for material design and performance customization in biomedical applications.
Additive manufacturing offers a revolutionary pathway for customising patient-specific metal implants. How-ever, clinical practice calls for balanced material properties besides a patient-matched geometry, including good biocompatibility, low elastic modulus, good material strength and enhanced wear resistance. This study dem-onstrates an in-situ microscale composition modulation method by laser powder bed fusion (LPBF) using a Mo2C/ Ti powder mixture, achieving adaptive microstructure and successfully combining balanced mechanical and wear properties in the Ti-7.5Mo-2.4TiC composites. The modulation is made through partial homogenisation of raw materials, leaving entangled Mo-rich and Mo-poor streaks around the molten pool boundary and a Ti-Mo matrix at the molten pool centre. By optimising volumetric energy density to 82.3 J/mm3, the modulated composition inhomogeneity produces an alternately laminated microstructure with entangled alpha and beta streaks around the molten pool boundary and mixed alpha+beta phases at the molten pool centre. Such that the molten pool boundary reveals a lower elastic modulus relative to the molten pool centre. The uneven allocation of elastic moduli throughout layers of molten pools enables a step-by-step deformation mode under compressive loading, lowering the component-related elastic modulus to 90.4 +/- 2.1 GPa; on the other hand, it suppresses crack propagation, extending the material's elongation to 16.4 +/- 1.4%. The synergistic effect of grain refinement and dispersion strengthening provided by in-situ precipitated TiC improves yield strength (936.9 +/- 19.8 MPa) and ultimate compressive strength (1415.5 +/- 23.1 MPa). The hard TiC also enhances the wear property, obtaining lower wear rates (down to 8.6 x 10-4 mm3N- 1m- 1) than the pure Ti. The balanced mechanical and wear properties could expand the potential of this composite in clinical use. More importantly, this LPBF-based approach creates a pathway for microscale composition modulation in material design and performance cus-tomisation towards biomedical applications.
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