Abstract
Machining and forming tools exposed to challenging environments require protective coatings to extend their lifetime and reliability. Although transition metal nitrides possess excellent strength and resistance against chemical attacks, they lack ductility and are prone to premature failure. Here, by investigating structural and mechanical properties of MoN-TaN superlattices with different bilayer thickness, we develop coatings with high fracture toughness and hardness, stemming from the formation of a metastable tetragonally distorted phase of TaN up to layer thicknesses of 2.5 nm. Density functional theory calculations and experimental results further reveal a metal-vacancy stabilized cubic Ta0.75N phase with an increased Young’s modulus but significantly lower fracture toughness. We further discuss the influence of coherency strains on the fracture properties of superlattice thin films. The close interplay between our experimental and ab initio data demonstrates the impact of phase formation and stabilization on the mechanical properties of MoN-TaN superlattices.
Highlights
Machining and forming tools exposed to challenging environments require protective coatings to extend their lifetime and reliability
We identified MoN/TaN as a promising material system, it did not make any link between mechanical properties and the most important tuning parameter known for significantly between 32.6 GPa (SL) architectures: the bilayer period
The rsTaN is predicted to slightly outperform its monolithic rsMoN0.5 counterpart in terms of ductility, whereas the behavior of MoN0.5/TaN SL seems to be largely influenced by the bilayer period
Summary
Machining and forming tools exposed to challenging environments require protective coatings to extend their lifetime and reliability. We expect that the combination of very similar shear modulus (124 GPa for the cubic MoN0.5 and 127 GPa for cubic, defect-free TaN, and 159 GPa for ζ-TaN) but notably different structural parameters could lead to a strong superlattice effect mirrored by significant enhancement of fracture properties. This would enable us to provide new insight on the relevant mechanism behind the fracture toughness enhancement observed for superlattice films apart from the wellknown hardness increase[21]
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