Enhancing the bio-corrosion resistance of Ni-free ZrCuFeAl bulk metallic glass through nitrogen plasma immersion ion implantation

•Nitrogen plasma immersion ion implantation (N-PIII) was used for Ni-free Zr-based BMG.•N-PIII treatment did not change the bulk amorphous structure of Ni-free Zr-based BMG.•N-PIII treatment produced a nitride-containing thin oxide film on BMG surface.•N-PIII treatment significantly enhanced resista...

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Bibliographic Details
Published in:Journal of alloys and compounds 2014-12, Vol.615, p.S660-S665
Main Authors: Huang, Her-Hsiung, Huang, Hsun-Miao, Lin, Mau-Chin, Zhang, Wei, Sun, Ying-Sui, Kai, Wu, Liaw, Peter K.
Format: Article
Language:English
Subjects:
Amorphous materials
Applied sciences
Bio-corrosion resistance
Corrosion
Corrosion potential
Corrosion prevention
Corrosion resistance
Exact sciences and technology
Ion implantation
Metals. Metallurgy
Ni-free Zr-based bulk metallic glass
Nickel
Nitrogen plasma
Nitrogen plasma immersion ion implantation
Pitting corrosion
Titanium
Zirconium
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Summary:•Nitrogen plasma immersion ion implantation (N-PIII) was used for Ni-free Zr-based BMG.•N-PIII treatment did not change the bulk amorphous structure of Ni-free Zr-based BMG.•N-PIII treatment produced a nitride-containing thin oxide film on BMG surface.•N-PIII treatment significantly enhanced resistance of BMG to bio-corrosion.•The N-PIII treated Ni-free Zr-based BMG has a high potential as biomedical implant. Improving the resistance of bulk metallic glass (BMG) to corrosion, particularly pitting, is crucial to the further development of this material. This study employed surface treatment based on nitrogen plasma immersion ion implantation (N-PIII) to enhance the bio-corrosion resistance of Ni-free Zr62.5Cu22.5Fe5Al10 BMG for application in bone implants. Resistance to bio-corrosion was evaluated by establishing potentiodynamic polarization curves in artificial saliva (AS) and simulated body fluid (SBF). Commercial pure Ti was used as the control. Results demonstrate that N-PIII treatment did not alter the bulk amorphous structure of Zr62.5Cu22.5Fe5Al10 BMG. Following N-PIII treatment, a nitride-containing 15nm thick oxide film was formed on the BMG. This film significantly improved resistance to bio-corrosion in both AS and SBF solutions. The N-PIII-treated BMG presented lower corrosion rates (50–67% less) and higher corrosion potential (800–1100mV more) than that observed in untreated BMG and Ti. The N-PIII treatment also significantly improved resistance of the BMG to pitting (increased pitting potential by 500–700mV). This is the first report of the outstanding resistance of Ni-free Zr-based BMG to bio-corrosion (i.e. corrosion rate 0.01μA/cm2; pitting potential >1200mV; corrosion potential >270mV) in simulated biological environments.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2014.01.098