Abstract
Tantalum nitride (TaNx) thin films were grown utilizing an inductively coupled plasma (ICP) assisted direct current (DC) sputtering, and 20–100% improved microhardness values were obtained. The detailed microstructural changes of the TaNx films were characterized utilizing transmission electron microscopy (TEM), as a function of nitrogen gas fraction and ICP power. As nitrogen gas fraction increases from 0.05 to 0.15, the TaNx phase evolves from body-centered-cubic (b.c.c.) TaN0.1, to face-centered-cubic (f.c.c.) δ-TaN, to hexagonal-close-packing (h.c.p.) ε-TaN phase. By increasing ICP power from 100 W to 400 W, the f.c.c. δ- TaN phase becomes the main phase in all nitrogen fractions investigated. The higher ICP power enhances the mobility of Ta and N ions, which stabilizes the δ-TaN phase like a high-temperature regime and removes the micro-voids between the columnar grains in the TaNx film. The dense δ-TaN structure with reduced columnar grains and micro-voids increases the strength of the TaNx film.
Highlights
Tantalum nitride (TaNx) has been widely used for wear resistance coatings, diffusion barrier layers, and highdensity magnetic recording media because of its good mechanical properties, chemical inertness, wide bandgap, and high-temperature stability (Choi and Yoon 2004; Han et al 1998; Laurila et al 2001; Li et al 1997)
We investigate the mechanical behavior and microstructural evolution of TaNx films grown at a temperature of 100 °C with changes of nitrogen fraction and Inductively coupled plasma (ICP) power
Inductively coupled plasma (ICP) assisted direct current (DC) sputtering has been used as a promising technique to improve the hardness of the TaNx thin film
Summary
Tantalum nitride (TaNx) has been widely used for wear resistance coatings, diffusion barrier layers, and highdensity magnetic recording media because of its good mechanical properties, chemical inertness, wide bandgap, and high-temperature stability (Choi and Yoon 2004; Han et al 1998; Laurila et al 2001; Li et al 1997). SADPs in the inset of BF TEM images display the phase change of TaNx films as a function of fN2 and ICP power.
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