Effect of immersion time on the passive and electrochemical response of annealed and nano-grained commercial pure titanium in Ringer's physiological solution at 37°C

In the present study, various electrochemical tests were used to investigate the passive and electrochemical response of annealed and nano-grained commercial pure Titanium in Ringer's physiological solution at 37°C. Nano-grained pure Titanium, which typically has an average grain size of 90±5nm...

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Bibliographic Details
Published in:Materials Science & Engineering C 2017-02, Vol.71, p.771-779
Main Authors: Fattah-alhosseini, Arash, Ansari, Ali Reza, Mazaheri, Yousef, Keshavarz, Mohsen K.
Format: Article
Language:English
Subjects:
Annealing
Conductivity
Corrosion
Dielectric Spectroscopy
Electricity
Electrochemical impedance spectroscopy
Electrochemistry
Electrochemistry - methods
Electronics industry
Grain refinement
Grain size
Isotonic Solutions - chemistry
Materials science
Mott–Schottky analysis
N-type semiconductors
Nano-grained
Nanoparticles - chemistry
Nanoparticles - ultrastructure
Oxide coatings
Particle size
Physiology
Pure titanium
Ringer's physiological solution
Roll bonding
Semiconductors
Size reduction
Spectroscopy
Temperature
Time Factors
Titanium
Titanium - chemistry
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Summary:In the present study, various electrochemical tests were used to investigate the passive and electrochemical response of annealed and nano-grained commercial pure Titanium in Ringer's physiological solution at 37°C. Nano-grained pure Titanium, which typically has an average grain size of 90±5nm, was obtained by six-cycle accumulative roll bonding process. Polarization and electrochemical impedance spectroscopy plots illustrated that as a result of grain refinement process, the passive response of the nano-grained sample was improved compared to that of its coarse-grained counterpart in Ringer's physiological solution. Mott–Schottky analysis indicated that the passive films behaved as n-type semiconductors in Ringer's physiological solution and grain refinement did not change the conductivity type of the passive films. Additionally, Mott–Schottky analysis showed that the donor density decreased by grain size reduction. Finally, nano-grained sample appeared to be more suitable for implant applications, mainly due to the formation of thicker and less defective oxide film. [Display omitted] •Grain size of pure Ti sample after 6cycles of accumulative roll bonding process reached to 90±5nm.•Nano-scale grain refinement led to a reduction in corrosion and passive current densities.•Nano-scale grain promoted formation of thicker and less defective passive film.•Nano-grained pure Ti is more suitable for implant applications compared to that of annealed sample.
ISSN:0928-4931
1873-0191
DOI:10.1016/j.msec.2016.10.057