High temperature mechanical properties and microstructure of hard TaSiN coatings

TL;DR

This study investigates the high temperature mechanical properties and microstructure of TaSiN coatings, revealing how nitrogen content influences phase composition, microstructure stability, and mechanical performance up to 500°C.

Contribution

It provides new insights into the relationship between nitrogen content, microstructure, and high temperature mechanical properties of TaSiN coatings.

Findings

Hardness decreases by only 15% at 500°C.

Fracture toughness increases with temperature.

Optimal composition is Ta55Si10N35, retaining high hardness and toughness.

Abstract

Room and high temperature mechanical properties of reactive magnetron sputtered TaSiN coatings were measured using nanoindentation (between 25C and 500C). Fracture toughness was also evaluated at a similar temperature range using the micropillar splitting method. The influence of the nitrogen concentration on the evolving phases and microstructure of the TaSiN coatings, before and after the high temperature testing, were examined by X-ray diffraction (XRD) and transmission electron microscopy (TEM) analysis. XRD spectra showed broad peaks with hexagonal $\gamma$-Ta2N as the main phase, with the cubic $\delta$-TaN phase emerging for higher N contents. Phase composition remained unchanged before and after the 500C tests. However, after the high temperature tests, TEM analysis showed the presence of an oxide surface layer, with a thickness that decreased (from 42 to 15 nm) with N content, due to residual oxygen diffusion, which replaces nitrogen to form amorphous SiOx. Beneath the oxide-rich surface layer, coatings exhibited a stable nanocrystalline columnar microstructure. Hardness and fracture toughness increased with N content, initially due to the formation of an amorphous Si-N tissue at grain boundaries, and for even higher N contents, due to the appearance of the hard cubic $\delta$-TaN phase. Hardness at 500C decreased only by 15%, while fracture toughness followed the opposite trend, due to increased plasticity with temperature. The optimum composition turned out to be Ta55Si10N35, which retained a hardness of 30 GPa at 500C, being also the toughest. These observations make this system very interesting for high temperature applications.