Structural Characterization of Mg-0.5Ca-xY Biodegradable Alloys-Reference-Cited by-同舟云学术

Structural Characterization of Mg-0.5Ca-xY Biodegradable Alloys

Published:2018-10 Issue: Volume:782 Page:129-135
ISSN:1662-9795
Container-title:Key Engineering Materials
language:
Short-container-title:KEM

Author:

Istrate Bogdan¹,Munteanu Corneliu¹,Lupescu Ștefan¹,Antoniac Vasile Iulian²,Sindilar Eusebiu³

Affiliation:

1. “Gheorghe Asachi” Technical University of Iasi

2. Polytechnic University of Bucharest

3. Ion Ionescu de la Brad University of Agricultural Sciences and Veterinary Medicine of Iași

Abstract

In recent years, researchers have been able to identify new materials with special properties that can be used in major medical fields. Magnesium-based materials used in orthopedics are an important alternative, being the third generation of biocompatible materials. A biodegradable magnesium-based material has the ability to degrade at a certain rate, is biocompatible, and together with other alloying elements ensures osteointegration. Mg-0.5Ca-xY biodegradable alloys will be developed in an induction melting furnace using ceramic crucibles, melting at 710-720 °C in the controlled atmosphere of 5.0 Ar. SEM analyses and X-ray diffraction reveals the size distribution of Mg-sized grains, with a hexagonal lattice and formation of compounds with the two alloying elements: Mg2Ca, Mg2Y, Mg24Y5uniformly arranged in the α-Mg matrix. The alloying elements influence the microstructure, the size of the α-Mg grains decreasing considerably.

Publisher

Trans Tech Publications, Ltd.

Subject

Mechanical Engineering,Mechanics of Materials,General Materials Science

Link

https://www.scientific.net/KEM.782.129.pdf

Reference21 articles.

1. Y.F. Zheng, X.N. Gu, F. Witte, Biodegradable metals, Materials Science and Engineering: R: Reports 77 (2014) 1-34.

2. S. Bălţatu, P. Vizureanu, D. Mareci, L.C. Burtan, C. Chiruţă, L.C. Trincă, Effect of Ta on the electrochemical behavior of new TiMoZrTa alloys in artificial physiological solution simulating in vitro inflammatory conditions, Materials and Corrosion 67(12) (2016).

3. M.G. Minciuna, P. Vizureanu, D.C. Achiţei, A.V. Sandu, The advanced characterization of a new alloy by Co-Cr-Mo system, JOAM 18(7-8) 2016 717-722.

4. J.V. Rau, I. Antoniac, M. Fosca, A. De Bonis, A.I. Blajan, C. Cotrut, V. Graziani, M. Curcio, A. Cricenti, M. Niculescu, M. Ortenzi, R. Teghil, Glass-ceramic coated Mg-Ca alloys for biomedical implant applications, Materials Science and Engineering C 64 (2016).

5. Y.M. Kim, C.D. Yim, H.S. Kim, B.S. You, Key factor influencing the ignition resistance of magnesium alloys at elevated temperatures, Scripta Materialia 65 (2011) 958–961.

Cited by 6 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Additive Manufactured Magnesium-Based Scaffolds for Tissue Engineering;Materials;2022-12-06

2. Treatment of Knee Osteochondral Fractures;Healthcare;2022-06-08

3. Electrochemical and In Vitro Biological Evaluation of Bio-Active Coatings Deposited by Magnetron Sputtering onto Biocompatible Mg-0.8Ca Alloy;Materials;2022-04-25

4. Magnesium-Based Alloys Used in Orthopedic Surgery;Materials;2022-02-02

5. Schematic review of plasma arc oxidation process for Mg Alloy Bio Implants;IOP Conference Series: Materials Science and Engineering;2021-01-01