Abstract
Binary Zr-Ti alloys spontaneously develop a tenacious and compact oxide layer when their fresh surface is exposed either to air or to aqueous environments. Electrochemical impedance spectroscopy (EIS) analysis of Zr-45Ti, Zr-25Ti, and Zr-5Ti exposed to simulated physiological solutions at 37 °C evidences the formation of a non-sealing bilayer oxide film that accounts for the corrosion resistance of the materials. Unfortunately, these oxide layers may undergo breakdown and stable pitting corrosion regimes at anodic potentials within the range of those experienced in the human body under stress and surgical conditions. Improved corrosion resistance has been achieved by prior treatment of these alloys using thermal oxidation in air. EIS was employed to measure the corrosion resistance of the Zr-Ti alloys in simulated physiological solutions of a wide pH range (namely 3 ≤ pH ≤ 8) at 37 °C, and the best results were obtained for the alloys pre-treated at 500 °C. The formation of the passivating oxide layers in simulated physiological solution was monitored in situ using scanning electrochemical microscopy (SECM), finding a transition from an electrochemically active surface, characteristic of the bare metal, to the heterogeneous formation of oxide layers behaving as insulating surfaces towards electron transfer reactions.
Highlights
Metallic biomaterials are used as prostheses in applications that require weight-bearing or to face mechanical forces, as in the case of skeletal elements or dental applications [1]
Electrochemical tests conditioning were done infor phosphate (PBS) atusing pH values ranging electrochemical characterization in terms of providing the highest corrosion resistance to materials
The corrosion resistance characteristics of the Zr-Ti alloys subjected to thermal asoxidation well as to in optimize thermal oxidation in a typical body fluid.electrochemical
Summary
Metallic biomaterials are used as prostheses in applications that require weight-bearing or to face mechanical forces, as in the case of skeletal elements or dental applications [1]. Metals 2020, 10, 166 do not have the strength, elasticity, ductility, and purity required by the different types of implants currently used in traumatology and orthopedics. For this reason, the addition of one or more alloying elements to the base metal is commonly conducted, modifying the crystalline structure, and its physical and mechanical properties. In comparison with other metallic biomaterials such as stainless steel and CoCr alloys, titanium-based materials exhibit similar strength, lower weight, and reduced elastic modulus (55 to 100 GPa), closer to those found in bone tissues (
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