Synthesis and Wear Characterization of Ultrasonic Electrodeposited Ni-TiN Thin Coatings

This work describes the use of a modified Watt nickel bath to prepare pure Ni and Ni-TiN thin coatings by the application of ultrasonic electrodeposition (UE) under pulse current (PC) conditions. X-ray diffraction (XRD), transmission electron microscopy (TEM), scanning electron microscopy (SEM), scanning probe microscopy (SPM) were used to investigate the influences of ultrasonic intensity on phase composition, surface topography, and microscopic structure. The Vickers hardness, wear resistance of Ni and Ni-TiN coatings, and coefficient of friction were also tested. The TEM, SEM, and SPM results showed that under the ultrasonic wave with the intensity of 30 W/cm(2), Ni-TiN coatings exhibited a glossy and uniform surface topography. For NT-2 coating with a superficial area of 4.102 mu m(2), the root means square (Rm s) roughness was 36.825 nm and the arithmetic mean roughness (Ra) was 22.658 nm. The average size of Ni grains was 47.1 nm, whereas that of TiN nanoparticles was observed as 23.2 nm. The diffraction angle of the coatings with disparate coating parameters in the XRD analysis was found to be similar to the Ni phase, however, the intensity of diffraction varied. The microhardness experiment showed that the minimum microhardness of the Ni film was 387.6 HV. Furthermore, the maximum microhardness value got from the Ni-TiN coating under the ultrasonic wave with an intensity of 30 W/cm(2) was 912.1 HV. Wear and friction evaluation showed that the loss in weight of Ni-TiN coatings performed with 30w/cm 2 ultrasonic intensity was the smallest, and the average friction coefficient was measured to be 0.39, thus exhibiting good resistance to wear.

Automated summary

This study utilized ultrasonic electrodeposition to prepare pure Ni and Ni-TiN thin coatings, investigating the effects of ultrasonic intensity on phase composition, surface topography, and microscopic structure. Ni-TiN coatings exhibited a glossy and uniform surface topography under an ultrasonic intensity of 30 W/cm^2.