[Zurück]

R Hahn, C. Fuger, G Habler, H. Bolvardi, P. Polcik, P.H. Mayrhofer, H. Riedl:
"Influence of the microstructure on the fracture characteristics of WB2-z based thin films";
als Vortrag angenommen für: Materials Science Colloquium, Lech; 19.04.2020 - 22.04.2020.

Physical vapor deposited transition metal borides are an emerging class of materials. Their inherent promising properties range from ultra-low compressibility, highest thermal stability to chemical inertness, allowing an application as protective coating in harsh environments. Our recent ab initio calculations suggest an attractive combination of high stiffness and appropriate high ductility for α-structured WB2-z. This leads to an interesting combination of high hardness while maintaining a sufficient fracture toughness. The stabilization of the α-structure over the intrinsically favored ω-structure is based on omnipresent growth defects in the PVD process. However, next to the stabilized phases also the morphology, especially column size and grain boundary interior, has a huge impact on the mechanical response.
Therefore, within this study we deposited various WB2-z coatings using different deposition techniques as well as parameters to modify the crystallite size and grain boundary constitution but also predominating phases. Subsequently, the mechanical properties of these coatings in the as deposited and annealed state have been analyzed by means of nanoindentation, microcantilever bending tests, and micropillar compression testing. Depending on the coating morphology, which varies from nanocrystalline (amorphous) to crystalline fibrous grown structures, the hardness, indentation modulus, and fracture toughness obtains a strong variation. The most significant variation was found in the fracture toughness of these coatings, we calculated values between 2.5 and 4.7 MPa√m. Furthermore, we critically evaluate the comparability of distinct micromechanical testing techniques assessing the fracture behavior also with respect to the residual stress state.

Fracture toughness, PVD, Coating