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Multicomponent TixNbCrAl nitride films deposited by dc and high-power impulse magnetron sputtering

Rui Shu, Hao Du, Grzegorz Sadowski, Megan Mahrokh Dorri, Johanna Rosén, Maurício A. Sortica, Daniel Primetzhofer, Daniel Lundin, Arnaud le Febvrier, Per Eklund

2021Surface and Coatings Technology22 citationsDOIOpen Access PDF

Abstract

Multicomponent TixNbCrAl nitride films were deposited on Si(100) substrates by reactive direct current magnetron sputtering (dcMS) and high power impulse magnetron sputtering (HiPIMS) in the absence of substrate heating and bias. Three single Ti, Nb, and Cr50Al50 targets were either driven by three dc or three HiPIMS power supplies. The Ti content in the films was varied by tuning the power applied to the Ti target. The composition was determined by ion beam analysis. The nitrogen content is nearly stoichiometric (48–50 at.%) in the HiPIMS series, while the dcMS are understoichiometric (39–45 at.%). The crystal structure, stress and density of the studied film were investigated by X-ray techniques and the microstructure was examined by scanning electron microscopy. All the Ti-containing films for both series exhibit an fcc NaCl-type phase structure. In particular, the dcMS series shows a (111) preferred orientation, resulting in a faceted surface morphology compared to a dense and smooth microstructure of the HiPIMS films. The compressive stress of the HiPIMS series (> 2.0 GPa) is significantly larger than the values of the dcMS series (<0.5 GPa). Nanoindentation measurements show a maximum hardness of 29.9 GPa and Young's modulus of 304 GPa were obtained in the HiPIMS series. The results may promote HiPIMS techniques for the synthesis of complex multicomponent films for the application aspect to protective and hard coatings.

Topics & Concepts

High-power impulse magnetron sputteringMaterials scienceMicrostructureSputter depositionNanoindentationComposite materialSputteringCavity magnetronNitrideThin filmPulsed DCAnalytical Chemistry (journal)NanotechnologyChemistryChromatographyLayer (electronics)Metal and Thin Film MechanicsDiamond and Carbon-based Materials ResearchBoron and Carbon Nanomaterials Research