Journal
FRONTIERS IN MATERIALS
Volume 8, Issue -, Pages -Publisher
FRONTIERS MEDIA SA
DOI: 10.3389/fmats.2021.634236
Keywords
titanium alloys; elasticity gradient; elastic modulus; surface deformation; instrumented indentation; stress-induced martensite
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Funding
- BIOTECH DENTAL company
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The study aimed to develop a thermo-mechanical strategy to create a radial elasticity gradient in a beta metastable Ti-Nb-Zr alloy, and to lower the elastic modulus of the alloy through mechanical deformation. Experimental results showed that shot-peening was an efficient way to induce surface martensitic transformation and create an elasticity gradient in beta metastable titanium alloys, potentially suitable for producing dental implants with mechanically enhanced biocompatibility.
The objective of this study was to develop a thermo-mechanical strategy to create a radial elasticity gradient in a beta metastable Ti-Nb-Zr alloy, and to characterize it in terms of microstructural and mechanical properties. A first investigation was conducted on thin samples of Ti-20Nb-6Zr (at.%) submitted to various thermo-mechanical treatments. Microstructure-properties relationships and elastic variability of this alloy were determined performing uniaxial tensile tests, X-ray diffraction and scanning and transmission electron microscopies. Based on these preliminary results, mechanical deformation was identified as a potential way to lower the elastic modulus of the alloy. In order to create elastically graded pieces, shot-peening was therefore carried out on thicker samples to engender surface deformation. In this second part of the work, local mechanical properties were evaluated by instrumented micro-indentation. Experimental observations demonstrated that shot-peening enabled to locally induce martensitic transformation on surface, and a decrease in indentation elastic modulus from 85 to 65 GPa over 400 mu m was highlighted. Surface deformation proved to be an efficient way of creating an elasticity gradient in beta metastable titanium alloys. This combination of material and process could be suitable to produce dental implants with mechanically enhanced biocompatibility.
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