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Corrosion Resistance of Nitinol Wires After Deformation

  • Stefan Zende
  • Katharina E. Freiberg
  • Franziska Dorner
  • Nils-Agne Feth
  • Andreas UndiszEmail author
SMST2019
  • 17 Downloads

Abstract

The corrosion resistance of thin NiTi wires in unstrained state and at 6% of pseudoelastic strain was determined by cyclic potentiodynamic polarization, considering a surface area of 2.3 cm2, equivalent to that of an actual minimally invasive implant. Surface finishing was carried out by mechanical polishing, electropolishing, and subsequent heat treatment in a salt bath furnace. Topography, microstructure, and composition of the respective surfaces were characterized in detail using light and electron microscopy, as well as glow discharge optical emission spectroscopy. Whereas breakdown below 1000 mV was observed for wires in mechanically polished condition in unstrained and strained state, wires in electropolished and electropolished + heat-treated condition exhibit no breakdown up to 1000 mV. Multiple testing reproduced uniform potentiodynamic polarization curves in unstrained and strained state. Accordingly, the observed formation of cracks in the surface oxide layer of wires in electropolished + heat-treated condition is concluded to be negligible in unstrained and strained state. Cause for the observed high performance of both the electropolished and the electropolished + heat-treated wires is apparently the smoothing of the initial surface that results in a homogeneous oxide layer even after heat treatment.

Keywords

Biocompatibility Pseudoelasticity Corrosion resistance Surface treatment 

Notes

Acknowledgements

Andreas Keck from G. Rau GmbH is acknowledged for supplying the mechanically polished wire. Two of the authors (AU and KEF) gratefully acknowledge financial support by the German Research Foundation (DFG, UN 341/3-1 and Inst 275/391-1).

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Copyright information

© ASM International 2019

Authors and Affiliations

  • Stefan Zende
    • 1
  • Katharina E. Freiberg
    • 2
  • Franziska Dorner
    • 1
  • Nils-Agne Feth
    • 1
  • Andreas Undisz
    • 2
    Email author
  1. 1.ADMEDES GmbHPforzheimGermany
  2. 2.Otto Schott Institute of Materials Research, Chair of Metallic MaterialsFriedrich-Schiller-UniversitätJenaGermany

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