https://orcid.org/0000-0003-2685-4808
References
- Magnuson M, Hultman L, Högberg H. Review of transition-metal diboride thin films. Vacuum. 2022;196:110567.
- Yao Y, Zhang Z, Jiao L. Development strategies in transition metal borides for electrochemical water splitting. Energy Environ Mater. 2021;5:470–485.
- Mayrhofer PH, Mitterer C, Wen JG, et al. Self-organized nanocolumnar structure in superhard {TiB2} thin films. Appl Phys Lett. 2005;86(13):1–3.
- Neidhardt J, Mráz S, Schneider JM, et al. Experiment and simulation of the compositional evolution of {Ti–B} thin films deposited by sputtering of a compound target. J Appl Phys. Sep. 2008;104(6):63304.
- Schnitter C, Petrov I, Zhirkov I, et al. Effect of low-energy ion assistance on the properties of sputtered ZrB2 films. Vacuum. 2021;195(October):110688.
- Thörnberg J, Palisaitis J, Hellgren N, et al. Microstructure and materials properties of understoichiometric TiBx thin films grown by HiPIMS. Surf Coatings Technol. 2020;404(October).
- Nedfors N, Tengstrand O, Lu J, et al. Superhard NbB2 −x thin films deposited by dc magnetron sputtering. Surf Coatings Technol. Oct. 2014;257:295–300.
- Berger M, Karlsson L, Larsson M, et al. Low stress {TiB2} coatings with improved tribological properties. Thin Solid Films. 2001;401(1–2):179–186.
- Mikula M, Grančič B, Roch T, et al. The influence of low-energy ion bombardment on the microstructure development and mechanical properties of TiBx coatings. Vacuum. 2011;85(9):866–870.
- Bakhit B, Palisaitis J, Thörnberg J, et al. Improving the high-temperature oxidation resistance of TiB2 thin films by alloying with Al. Acta Mater. 2020;196:677–689.
- Kalfagiannis N, Volonakis G, Tsetseris L, et al. Excess of boron in TiB2 superhard thin films: A combined experimental and ab initio study. J Phys D Appl Phys. 2011;44(38).
- Palisaitis J, Dahlqvist M, Hall AJ, et al. Where is the unpaired transition metal in substoichiometric diboride line compounds? Acta Mater. 2021;204:116510.
- Veprek S. Recent search for new superhard materials: Go nano!. J Vac Sci Technol A Vacuum, Surfaces, Film. 2013;31(5):50822.
- Veprek S, Karvankova P, Veprek-Heijman MGJ. Possible role of oxygen impurities in degradation of nc-Ti N/ a-Si 3 N 4 nanocomposites. J Vac Sci Technol B Microelectron Nanom Struct Process Meas Phenom. 2005;23(6):L17–L21.
- Fuger C, Moraes V, Hahn R, et al. Influence of Tantalum on phase stability and mechanical properties of WB2. MRS Commun. Mar. 2019;9(01):375–380.
- Daniel R, Meindlhumer M, Zalesak J, et al. Fracture toughness enhancement of brittle nanostructured materials by spatial heterogeneity: a micromechanical proof for CrN/Cr and TiN/SiOx multilayers. Mater Des. 2016;104:227–234.
- Liu S, Wheeler JM, Davis CE, et al. The effect of Si content on the fracture toughness of CrAlN/Si3N4 coatings. J Appl Phys. 2016;119(2):25305.
- Bartosik M, Hahn R, Zhang ZL, et al. Fracture toughness of Ti-Si-N thin films. Int J Refract Met Hard Mater. 2018;72(October 2017):78–82.
- Bartosik M, Rumeau C, Hahn R, et al. Fracture toughness and structural evolution in the TiAlN system upon annealing. Sci Rep. 2017;7(1):1–9.
- Hahn R, Kirnbauer A, Bartosik M, et al. Toughness of Si alloyed high-entropy nitride coatings. Mater Lett. 2019;251:238–240.
- Moritz Y, Kainz C, Tkadletz M, et al. Microstructure and mechanical properties of arc evaporated Ti(Al,Si)N coatings. Surf Coatings Technol. 2021;421:127461.
- Kainz C, Pohler M, Tkadletz M, et al. The influence of bias voltage on structure, thermal stability and mechanical properties of arc evaporated Cr0.69Ta0.20B0.11N coatings. Surf Coatings Technol. 2021;428(September):127867.
- Best JP, Zechner J, Wheeler JM, et al. Small-scale fracture toughness of ceramic thin films: the effects of specimen geometry, ion beam notching and high temperature on chromium nitride toughness evaluation. Philos Mag. 2016;96(32–34):3552–3569.
- Seidl WM, Bartosik M, Kolozsvári S, et al. Influence of Ta on the fracture toughness of arc evaporated Ti-Al-N. Vacuum. 2018;150:24–28.
- Sperr M, Zhang ZL, Ivanov YP, et al. Correlating elemental distribution with mechanical properties of TiN/SiNx nanocomposite coatings. Scr Mater. 2019;170:20–23.
- Glechner T, Lang S, Hahn R, et al. Correlation between fracture characteristics and valence electron concentration of sputtered Hf-C-N based thin films. Surf Coatings Technol. 2020;399(July):126212.
- Glechner T, Hahn R, Zauner L, et al. Structure and mechanical properties of reactive and non-reactive sputter deposited WC based coatings. J Alloys Compd. 2021;885:161129.
- Glechner T, Hahn R, Wojcik T, et al. Assessment of ductile character in superhard Ta-C-N thin films. Acta Mater. Oct. 2019;179:17–25.
- Zauner L, Hahn R, Aschauer E, et al. Assessing the fracture and fatigue resistance of nanostructured thin films. Acta Mater. 2022;239:118260.
- Matoy K, Schönherr H, Detzel T, et al. A comparative micro-cantilever study of the mechanical behavior of silicon based passivation films. Thin Solid Films. 2009;518(1):247–256.
- Brinckmann S, Matoy K, Kirchlechner C, et al. On the influence of microcantilever pre-crack geometries on the apparent fracture toughness of brittle materials. Acta Mater. Sep. 2017;136:281–287.
- Brinckmann S, Kirchlechner C, Dehm G. Stress intensity factor dependence on anisotropy and geometry during micro-fracture experiments. Scr Mater. 2017;127:76–78.
- Pippan R, Wurster S, Kiener D. Fracture mechanics of micro samples: Fundamental considerations. Mater Des. 2018;159:252–267.
- Fuger C, Hahn R, Hirle A, et al. Revisiting the origins of super-hardness in TiB2 + z thin films – Impact of growth conditions and anisotropy. Surf Coatings Technol. 2022: 128806.
- Fuger C, Hahn R, Zauner L, et al. Anisotropic super-hardness of hexagonal WB2 ± z thin films. Mater Res Lett. 2022;10(2):70–77.
- Schiøtz J, Di Tolla FD, Jacobsen KW. Softening of nanocrystalline metals at very small grain sizes. Nature. 1998;391(6667):561–563.
- Zhang S, Sun D, Fu Y, et al. Recent advances of superhard nanocomposite coatings: a review. Surf Coatings Technol. 2003;167(2–3):113–119.
- Oliver WC, Pharr GM. An improved technique for determining hardness and elastic modulus using load and displacement sensing indentation experiments. J Mater Res. 1992;7(6):1564–1583.