Balance between oxidation and tribological behaviors at elevated temperatures of Hf1-xWxN films by optimizing W content

Wear resistance and anti-oxidization are required for the binary transitional metal nitride coatings when they are applied as protective coating on cutting tools. The dope with other transitional metal elements is one of the effective strategies to enhance the wear resistance of binary transitional metal nitride coatings. In this study, Hf1-xWxN ternary coatings with various W content were prepared by DC magnetron sputtering. The hardness, toughness and tribological properties of Hf1-xWxN coatings varied with W doping amounts were investigated. The results show that the Hf1-xWxN coatings with the x range of 0-1 maintain B1 structure (FCC single solid solution phase). High hardness (35.3 GPa) and enhanced toughness (3.5 MPa m1/2) are obtained from Hf1-xWxN coating with x = 0.73 (Hf0.27W0.73N). The friction coefficient and wear rate of Hf0.27W0.73N are as low as 0.38 and 2.48 x 10-6 mm3/Nm at room temperature, while they are 0.42 and 8.12 x 10-6 mm3/Nm at the temperature of 400 degrees C. The excellent friction and wear properties of Hf1-xWxN coatings at elevated temperatures are mainly attributed to the enhanced mechanical properties and the lubrication of tungsten oxides (WO3). The balance between oxidation and tribological behaviors of Hf1-xWxN coatings are achieved by optimizing W content.

Automated summary

The wear resistance of binary transitional metal nitride coatings can be enhanced by doping with tungsten. Hf1-xWxN ternary coatings with various W content were prepared and the influence of W doping on hardness, toughness, and tribological properties was investigated. The results show that Hf0.27W0.73N coating exhibits high hardness and improved toughness, with low friction coefficient and wear rate at room temperature.