Properties of ZrNx films with x > 1 deposited by reactive radiofrequency magnetron sputtering

Thin ZrN_x films have been prepared by reactive radiofrequency magnetron sputtering varying the nitrogen partial pressure in the range 0-3.26 Pa. The films have been analyzed by X-ray photoelectron spectroscopy (XPS) and by optical characterization in the UV-Vis-IR range. The cross-section and surface morphology of the samples were examined by means of field emission gun-scanning electron microscopy. The effects of the nitrogen partial pressure on the ZrN_x films stoichiometry have been studied correlating the N 1s photoelectron peaks with different bounding states for the zirconium nitride. The XPS depth profile analysis has revealed the presence of metastable phases (ZrN₂, Zr₃N₄) that vanishes when lowering the nitrogen partial pressure. The optical analysis has permitted to distinguish two different behaviours of the deposited samples in the visible range: semi-transparent and absorbent. Drude-Lorentz model fitted the behaviour of absorbent films, while the O'Leary model was applied to the semi-transparent ones. The semi-transparent films had a band gap varying between 2.36 and 2.42 eV, typical values of N-rich zirconium nitride films. Morphological analysis showed a compact and dense columnar structure for all the samples. A simple growth model explains the presence of the different nitride phases considering implantation and re-sputtering effects.