Microstructures, aging behaviour and mechanical properties in hydrogen and chloride media of backward extruded Mg–Y based biomaterials

Microstructures, aging behaviour from room temperature to 300°C and mechanical properties in different media of backward extruded (BE) Mg–Y based biomaterial have been investigated. The results reveal that BE-Mg–Y based alloy is mainly composed of polygon-shaped grains and fine precipitates. The res...

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Bibliographic Details
Published inJournal of the mechanical behavior of biomedical materials Vol. 17; pp. 176 - 185
Main Authors Peng, Qiuming, Ma, Ning, Fang, Daqing, Li, Hui, Liu, Riping, Tian, Yongjun
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier Ltd 01.01.2013
Subjects
Age hardening behaviour
Alloys - chemistry
Beryllium base alloys
Biocompatible Materials - chemistry
Biomaterials
Biomedical materials
Chlorides - chemistry
Hardness
Hydrogen - chemistry
Hydrogen and chloride media
Immersion
Magnesium
Magnesium - chemistry
Materials Testing
Mechanical Phenomena
Mechanical properties
Media
Mg biomaterials
Microstructure
Solutions
Surgical implants
Temperature
Time Factors
Yttrium - chemistry
Mechanical properties
Hydrogen and chloride media
Mg biomaterials
Age hardening behaviour
Microstructure
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Summary:Microstructures, aging behaviour from room temperature to 300°C and mechanical properties in different media of backward extruded (BE) Mg–Y based biomaterial have been investigated. The results reveal that BE-Mg–Y based alloy is mainly composed of polygon-shaped grains and fine precipitates. The results of aging response show that BE-Mg–Y based alloy exhibits remarkable age hardening behaviour when the aging temperature is 200°C and higher. The high mechanical properties of aged BE-Mg–Y based alloy are mostly associated with fine microstructure, solid solution strengthening and the existence of homogeneous precipitates. The hydrogen embrittlement dependence on the aging time is confirmed in BE-Mg–Y based alloy. Additionally, the strength and elongation of BE-Mg–Y based alloy are significantly influenced by the ion concentration in media. These results offer some implications for understanding the reduced strength of Mg based implants in body environment. It is demonstrated that the temporary high mechanical strength in air of BE-Mg–Y based biomaterials is insufficient to evaluate the in vivo mechanical integrity.
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ISSN:1751-6161
1878-0180
DOI:10.1016/j.jmbbm.2012.08.017