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Development of new beta/alpha ''-Ti-Nb-Zr biocompatible coating with low Young's modulus and high toughness for medical applications

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    0498454 - BC 2019 RIV GB eng J - Journal Article
    Frutos, E. - Karlík, M. - Jiménez, J. A. - Langhansová, Helena - Lieskovská, Jaroslava - Polcar, A.
    Development of new beta/alpha ''-Ti-Nb-Zr biocompatible coating with low Young's modulus and high toughness for medical applications.
    Materials and Design. Roč. 142, Mar 15 (2018), s. 44-55. ISSN 0264-1275. E-ISSN 1873-4197
    Institutional support: RVO:60077344
    Keywords : Biomaterials * Non-toxic beta-rich Ti coatings * Martensitic phase transformation * Rietveld XRD quantification * Transmission electron microscopy * Low Young's modulus
    OECD category: Genetics and heredity (medical genetics to be 3)
    Impact factor: 5.770, year: 2018

    Ideal biomaterials to fabricate orthopedic implants, especially for load-bearing joint replacements, should include only non-toxic elements with good biocompatibility, high corrosion resistance and surface bioactivity, together with a good combination of mechanical properties. Based on these criteria, a manufacturing approach based on sputtering techniques can be ideal to develop coatings free of toxic elements tailored for advanced applications on pure titanium or titanium alloys used in biomedical applications. In this work, the ternary Ti-Nb-Zr system was used to develop non-toxic beta-rich Ti coatings with several complex microstructures by careful control of Nb and Zr concentration and deposition parameters, such as bias voltage. Depending on the alloy chemistry and processing, the coating included variable amounts of alpha-, alpha '' and beta-phases of Ti with different morphologies and crystallographic texture. Mechanical properties of every coating is largely determined by the micro-structure present, which is directly related to bias voltage used during sputtering process. Thus, hardness values change as a function of the compressive residual stresses magnitude and Young's modulus decreased from 63 GPa, at 0 V, to 47 GPa, at63 V, being this value close to human bone (similar to 30 GPa). After that, Young's modulus progressively increases to 89 GPa, at148 V. On the other hand, bioactivity of the coating is practically doubled when compared to Ti6AL4V alloy. (c) 2018 Elsevier Ltd. All rights reserved.
    Permanent Link: http://hdl.handle.net/11104/0290824

     
     
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