Potentiometric scanning electrochemical microscopy for monitoring the pH distribution during the self-healing of passive titanium dioxide layer on titanium dental root implant exposed to physiological buffered (PBS) medium

Abdelilah Asserghine, Dániel Filotás, Bálint Németh, L. Nagy, G. Nagy

Research output: Contribution to journalArticle

2 Citations (Scopus)

Abstract

Spontaneously forming oxide film protects titanium containing medical implants against corrosion and it also mitigates the release of poisonous ionic species into the surrounding life tissues. The self-healing kinetics of the film that lost integrity upon some impact is an important feature. In this short paper, the recent results obtained investigating the formation of the oxide film using potentiometric SECM and electrochemical impedance spectroscopy is presented. Ti G4 dental root implant was used as sample surface immersed in PBS medium. SECM in potentiometric mode, using antimony microprobe was applied to monitor the pH change in different times over freshly polished G4 titanium by recording a series of consecutive line scans, to find out the mechanism of TiO2 formation. Impedance spectroscopic experiments were carried out to investigate how the corrosion resistance of freshly polished titanium G4 surface changes by the exposition time.

Original languageEnglish
Pages (from-to)1-4
Number of pages4
JournalElectrochemistry Communications
Volume95
DOIs
Publication statusPublished - Oct 1 2018

Fingerprint

Titanium
Titanium dioxide
Microscopic examination
Scanning
Oxide films
Monitoring
Antimony
Electrochemical impedance spectroscopy
Corrosion resistance
Tissue
Corrosion
Kinetics
titanium dioxide
Experiments

Keywords

  • Antimony microelectrode
  • Kinetics of TiO formation
  • SECM
  • Self-healing TiO formation
  • Ti G4 dental implant

ASJC Scopus subject areas

  • Electrochemistry

Cite this

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abstract = "Spontaneously forming oxide film protects titanium containing medical implants against corrosion and it also mitigates the release of poisonous ionic species into the surrounding life tissues. The self-healing kinetics of the film that lost integrity upon some impact is an important feature. In this short paper, the recent results obtained investigating the formation of the oxide film using potentiometric SECM and electrochemical impedance spectroscopy is presented. Ti G4 dental root implant was used as sample surface immersed in PBS medium. SECM in potentiometric mode, using antimony microprobe was applied to monitor the pH change in different times over freshly polished G4 titanium by recording a series of consecutive line scans, to find out the mechanism of TiO2 formation. Impedance spectroscopic experiments were carried out to investigate how the corrosion resistance of freshly polished titanium G4 surface changes by the exposition time.",
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T1 - Potentiometric scanning electrochemical microscopy for monitoring the pH distribution during the self-healing of passive titanium dioxide layer on titanium dental root implant exposed to physiological buffered (PBS) medium

AU - Asserghine, Abdelilah

AU - Filotás, Dániel

AU - Németh, Bálint

AU - Nagy, L.

AU - Nagy, G.

PY - 2018/10/1

Y1 - 2018/10/1

N2 - Spontaneously forming oxide film protects titanium containing medical implants against corrosion and it also mitigates the release of poisonous ionic species into the surrounding life tissues. The self-healing kinetics of the film that lost integrity upon some impact is an important feature. In this short paper, the recent results obtained investigating the formation of the oxide film using potentiometric SECM and electrochemical impedance spectroscopy is presented. Ti G4 dental root implant was used as sample surface immersed in PBS medium. SECM in potentiometric mode, using antimony microprobe was applied to monitor the pH change in different times over freshly polished G4 titanium by recording a series of consecutive line scans, to find out the mechanism of TiO2 formation. Impedance spectroscopic experiments were carried out to investigate how the corrosion resistance of freshly polished titanium G4 surface changes by the exposition time.

AB - Spontaneously forming oxide film protects titanium containing medical implants against corrosion and it also mitigates the release of poisonous ionic species into the surrounding life tissues. The self-healing kinetics of the film that lost integrity upon some impact is an important feature. In this short paper, the recent results obtained investigating the formation of the oxide film using potentiometric SECM and electrochemical impedance spectroscopy is presented. Ti G4 dental root implant was used as sample surface immersed in PBS medium. SECM in potentiometric mode, using antimony microprobe was applied to monitor the pH change in different times over freshly polished G4 titanium by recording a series of consecutive line scans, to find out the mechanism of TiO2 formation. Impedance spectroscopic experiments were carried out to investigate how the corrosion resistance of freshly polished titanium G4 surface changes by the exposition time.

KW - Antimony microelectrode

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KW - Self-healing TiO formation

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