• Zdrojek, Mariusz
• Domaradzki, J.
• Mazur, M.
• Judek, Jarosław
• Kaczmarek, D.
• Wojcieszak, D.
• Grobelny, M.
• Świniarski, Michał
• Kalisz, M.

Abstract

In this paper, comparative studies on the mechanical and corrosion properties of hybrid coating systems based on titanium dioxide thin films (200. nm) and graphene monolayers have been investigated. The pure titanium dioxide layers were deposited on a Ti6Al4V alloy surface using the conventional magnetron sputtering process and the so-called "magnetron sputtering with modulated plasma" process. A graphene monolayer was transferred to a titanium alloy substrate using the "PMMA-mediated" method. The structural characteristics of the obtained thin films were examined by using Raman spectroscopy, X-ray diffraction (XRD), a scanning electron microscope (SEM) and atomic force microscopy (AFM) measurement. The mechanical properties, i.e. hardness, were tested by using a nanoindenter test. The corrosion properties of the coatings were determined by analysis of the voltammetric curves.The deposited TiO<inf>2</inf> thin film prepared by the conventional magnetron sputtering process consisted of visible grains with the size of ca. 50-100nm and had a nanocrystalline anatase phase (TiO<inf>2</inf>(a)). The TiO<inf>2</inf> thin film deposited by plasma-modulated sputtering had a nanocrystalline rutile structure TiO<inf>2</inf>(r) and its surface consisted of big, irregular grains and was not as homogeneous as the coating prepared by the conventional method.The hardness of TiO<inf>2</inf>(a) and TiO<inf>2</inf>(r) thin films was equal: 7.59GPa and 14.2GPa, respectively.Graphene transferred to a titanium dioxide thin film surface was a single layer without defects. Unfortunately, the nanoindentation method, used to measure the hardness of the titanium dioxide/graphene coating systems, is not sensitive to one or few atomic layers of graphene deposited on the top of the coating structures. Therefore, the measurement did not reveal changes of titanium dioxide thin film hardness after graphene deposition, in comparison with uncoated TiO<inf>2</inf> thin films such as TiO<inf>2</inf>(a) and TiO<inf>2</inf>(r) thin films. Futhermore, the graphene monolayer can be very easily removed from the titanium dioxide thin film surface (e.g. by scratching).The best corrosion properties (the lower value of corrosion current density) were obtained for sample Ti6Al4V coated with a TiO<inf>2</inf>(a) thin film. A deposition graphene monolayer on the top of all tested thin films improves the corrosion potential (E<inf>corr</inf>) value, which is much more positive than E<inf>corr</inf> registered for the other samples. A positive value of the corrosion potential is characteristic of materials with low electrochemical activity and thereby very good corrosion resistance. Moreover, these coatings systems maintain stability of the mechanical properties during the corrosion process. © 2015 Elsevier B.V.

Topics

• Deposition
• density
• impedance spectroscopy
• surface
• grain
• corrosion
• phase
• scanning electron microscopy
• x-ray diffraction
• thin film
• atomic force microscopy
• hardness
• nanoindentation
• defect
• titanium
• titanium alloy
• current density
• Raman spectroscopy