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Anisotropic super-hardness of hexagonal WB<sub>2±<i>z</i></sub> thin films

C. Fuger, Rainer Hahn, L. Zauner, Tomasz Wójcik, M. Weiss, Andreas Limbeck, O. Hunold, P. Polcik, H. Riedl

2022Materials Research Letters41 citationsDOIOpen Access PDF

Abstract

Transition metal diboride-based thin films are promising candidates to replace state-of-the-art protective and functional coating materials due to their unique properties. Here, we focus on hexagonal WB2-z, showing that the AlB2 structure is stabilized by B vacancies exhibiting its energetic minima at sub-stoichiometric WB1.5. Nanoindentation reveals super-hardness of 0001 oriented α-WB2-z coatings, linearly decreasing by more than 15 GPa with predominant 101¯1 orientation. This anisotropy is attributed to differences in the generalized stacking fault energy of basal and pyramidal slip systems, highlighting the feasibility of tuning mechanical properties by crystallographic orientation relations.

Topics & Concepts

Materials scienceNanoindentationStacking-fault energyAnisotropyHexagonal crystal systemCrystallographyStackingStoichiometryThin filmStacking faultCondensed matter physicsCoatingSlip (aerodynamics)NanotechnologyComposite materialMicrostructureDislocationNuclear magnetic resonanceThermodynamicsPhysicsOrganic chemistryChemistryQuantum mechanicsMXene and MAX Phase MaterialsMetal and Thin Film MechanicsBoron and Carbon Nanomaterials Research
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