Highly Dispersed Cu Produced by Mechanical Stress-Activated Redox Reaction to Establish Galvanic Corrosion in Fe Implant

Abstract: Fe has immense potential for biodegradable orthopedic applications, but it degrades slowly in the physiological environment. Inducing galvanic couple by alloying Cu to Fe using ball milling is a promising approach. However, the ductile nature of Cu leads to the cold welding of a large amount of Cu powder during ball milling, which makes it difficult to disperse uniformly in the Fe matrix. Here, a Fe−CuO implant with highly dispersed Cu particles in the matrix was developed by shift-speed ball milling and selec… Show more

“…It is one of the physical characteristics that determine the corrosion of biomedical implants, the other being the thermodynamic forces (redox reactions). [14][15][16] This method of preventing corrosion is mostly affected by fretting action which ruptures the coated layer and initiates cracks and forms metal atoms on the surface capable of accelerating corrosion. [17] Thus, coating materials must possess high abrasion resistance and must be impervious and non-toxic to the human body.…”

“…One of the most effective methods for preventing corrosion is by the use of a surface oxide layer coating technique acting as a kinetic barrier. It is one of the physical characteristics that determine the corrosion of biomedical implants, the other being the thermodynamic forces (redox reactions) [14–16] . This method of preventing corrosion is mostly affected by fretting action which ruptures the coated layer and initiates cracks and forms metal atoms on the surface capable of accelerating corrosion [17] .…”

Corrosion Prevention of Biomedical Implants: Surface Coating Techniques Perspective

“…It is one of the physical characteristics that determine the corrosion of biomedical implants, the other being the thermodynamic forces (redox reactions). [14][15][16] This method of preventing corrosion is mostly affected by fretting action which ruptures the coated layer and initiates cracks and forms metal atoms on the surface capable of accelerating corrosion. [17] Thus, coating materials must possess high abrasion resistance and must be impervious and non-toxic to the human body.…”

“…One of the most effective methods for preventing corrosion is by the use of a surface oxide layer coating technique acting as a kinetic barrier. It is one of the physical characteristics that determine the corrosion of biomedical implants, the other being the thermodynamic forces (redox reactions) [14–16] . This method of preventing corrosion is mostly affected by fretting action which ruptures the coated layer and initiates cracks and forms metal atoms on the surface capable of accelerating corrosion [17] .…”

Corrosion Prevention of Biomedical Implants: Surface Coating Techniques Perspective

Microstructure, mechanical and corrosion properties of FeCrNiCoMnSi0.1 high-entropy alloy coating via TIG arc melting technology and high-frequency ultrasonic impact with welding