Sikora-Jasinska, M., Mostaed, E., Mostaed, Ali, Beanland, R., Mantovani, D. and Vedani, M. (2017) Fabrication, mechanical properties and in vitro degradation behavior of newly developed ZnAg alloys for degradable implant applications. Materials Science and Engineering : C , 77 . pp. 1170-1181. doi:10.1016/j.msec.2017.04.023 ISSN 0928-4931.

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Abstract

Zn and Zn-based alloys have been recognized as highly promising biodegradable materials for orthopedic implants and cardiovascular stents, due to their proved biocompatibility and, more importantly, lower corrosion rates compared to Mg alloys. However, pure Zn has poor mechanical properties. In this study, Ag is used as a promising alloying element to improve the mechanical properties of the Zn matrix as well as its biocompatibility and antibacterial properties. Accordingly, we design three ZnAg alloys with Ag content ranging from 2.5 to 7.0wt% and investigate the influence of the Ag content on mechanical and corrosion behavior of the alloys. The alloys are developed by casting process and homogenized at 410°C for 6h and 12h, followed by hot extrusion at 250°C with extrusion ratio of 14:1. Degradation behavior is assessed by electrochemical and static immersion tests in Hank's modified solution. Microstructural analysis reveals that hot extrusion significantly reduces the grain size of the alloys. Zn-7.0%Ag alloy shows a reasonably equiaxed and considerably refined microstructure with mean grain size of 1.5μm. Tensile tests at room temperature suggest that increasing the Ag content steadily enhances the tensile strength, while it does not affect the tensile ductility significantly. Zn-7.0%Ag shows high yield strength and ultimate tensile strength of 236MPa and 287MPa, respectively, which is due to the grain refinement and high volume fraction of fine AgZn3 particles precipitating along the grain boundaries during the extrusion process. Among all these alloys, Zn-7.0%Ag displayed superplasticity over a wide range of strain rates (from 5×10(-4)s(-1) to 1.0×10(-2)s(-1)) providing the possibility of exploiting forming processes at rapid rates and/or even at lower temperatures. In addition, extruded alloys exhibit slightly faster degradation rate than pure Zn. X-ray diffraction results show the presence of ZnO and Zn(OH)2 on the degraded surfaces. Moreover, scanning electron microscopy imaging reveals that micro-galvanic corrosion is more pronounced on the alloys with higher Ag content due to the higher volume fraction of AgZn3 particles. [Abstract copyright: Copyright © 2017 Elsevier B.V. All rights reserved.]

Item Type:	Journal Article
Divisions:	Faculty of Science, Engineering and Medicine > Science > Physics
SWORD Depositor:	Library Publications Router
Journal or Publication Title:	Materials Science and Engineering : C
Publisher:	Elsevier Inc.
ISSN:	0928-4931
Official Date:	1 August 2017
Dates:	Date Event 1 August 2017 Published 2 April 2017 Available 6 April 2017 Accepted
Volume:	77
Page Range:	pp. 1170-1181
DOI:	10.1016/j.msec.2017.04.023
Status:	Peer Reviewed
Publication Status:	Published
Reuse Statement (publisher, data, author rights):	** From PubMed via Jisc Publications Router. ** History: ** received: 15-12-2016 ** accepted: 02-04-2017
Access rights to Published version:	Restricted or Subscription Access

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