Abstract
Tantalum silicon nitride (Ta–Si–N) films were synthesized on Si substrate via magnetron sputtering. The structure and properties of the Ta–Si–N films were investigated as a function of the N2 content in the N2/Ar gas mixture. Increasing the N2 percentage in the gas mixture from 7% to 20% changed the film structure from textured hexagonal (hex) Ta2N to nontextured hex Ta2N to a mixture of face-centered cubic (fcc) TaN and hex Ta2N, and finally to fcc TaN. X-ray photoelectron spectroscopy showed Ta–N and Si–N bonds in the films. The film microstructure was found to change from columnar morphology with visible amorphous boundaries (at 13% N2) to columnar morphology with absence of amorphous boundaries (at 15% N2). Increasing N2 content increased hardness in the films with those deposited with 13–15% N2 displaying the highest hardness of ~40 ± 2 GPa. In addition, the 13% N2 films showed a ratio of H/E* > 0.11, elastic recovery of ~60%, low coefficient of friction of 0.6, reduced wear rate (7.09 × 10−6 mm3/N·m), and remained thermally stable up to 800 °C. The results suggest that the Ta–Si–N films have high potential as hard tribological nanocomposite coatings.
Highlights
Transition metal nitrides MeN (Me: transition metal) possess attractive physical, chemical, and mechanical properties that make them candidate materials for several engineering applications such as protective hard coatings, wear-resistant layers, diffusion barriers, and thin film resistors in microelectronics
The results suggest that the Tantalum silicon nitride (Ta–Si–N) films have high potential as hard tribological nanocomposite coatings
The aim of this study is to analyze the effect of the N2 content in the plasma on the structure, microstructure and mechanical properties of nanocrystalline, low Si content (≤ 20 at.%) Ta–Si–N films
Summary
Transition metal nitrides MeN (Me: transition metal) possess attractive physical, chemical, and mechanical properties that make them candidate materials for several engineering applications such as protective hard coatings, wear-resistant layers, diffusion barriers, and thin film resistors in microelectronics. Of particular interest are the Nb-N and Ta-N systems since they exhibit several metastable and stable phases. Ta–N exhibits orthorhombic (orth) Ta4 N, hexagonal (hex) Ta6 N2.57 , hex Ta2 N, hex TaN0.8 , hex (WC type) ε-TaN, face-centered cubic (fcc, NaCl-type) δ-TaN, hex Ta5 N6 , tetragonal (tetr) Ta4 N5 , and orth Ta3 N5 phases. Variation of mechanical and electrical properties exists for each one of the aforementioned phases [7,8,9,10,11,12]. The relatively low oxidation resistance and thermal stability limits the use of various MeNs to temperatures below 600 ◦ C
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