Tissue phase affected fracture toughness of nano-columnar TiB₂₊z thin films

Fuger, Christoph; Hahn, Rainer; Hirle, Anna Viktoria; Wojcik, Tomasz; Kutrowatz, Philip; Bohrn, Fabian; Hunold, O.; Polcik, P.; Riedl-Tragenreif, Helmut

doi:10.1080/21663831.2023.2204120

Record link:

http://hdl.handle.net/20.500.12708/190927
https://doi.org/10.34726/5316

Title:

Tissue phase affected fracture toughness of nano-columnar TiB₂₊z thin films

Citation:

Fuger, C., Hahn, R., Hirle, A. V., Wojcik, T., Kutrowatz, P., Bohrn, F., Hunold, O., Polcik, P., & Riedl-Tragenreif, H. (2023). Tissue phase affected fracture toughness of nano-columnar TiB₂₊z thin films. Materials Research Letters, 11(8), 613–622. https://doi.org/10.34726/5316

reposiTUm DOI:

10.34726/5316

Publisher DOI:

10.1080/21663831.2023.2204120

Publication Type:

Article - Original Research Article

Language:

English

Authors:

Fuger, Christoph
Hahn, Rainer
Hirle, Anna Viktoria
Wojcik, Tomasz
Kutrowatz, Philip
Bohrn, Fabian
Hunold, O.
Polcik, P.
Riedl-Tragenreif, Helmut

Organisational Unit:

E308-01-2 - Forschungsgruppe Angewandte Oberflächentechnik
E308-03-1 - Forschungsgruppe Metallurgische Verarbeitungstechnologien

Journal:

Materials Research Letters

ISSN:

2166-3831

Date (published):

2023

Number of Pages:

Publisher:

TAYLOR & FRANCIS INC

Peer reviewed:

Yes

Keywords:

fracture toughness; micro-mechanical testing; TiB 2; tissue phase; Transition metal diborides

Abstract:

Structural imperfections such as nano-columnar tissue phases constitute a morphological design feature in protective thin films. Especially in the rising group of PVD transition metal diborides, excess Boron is known to form nm-sized B-rich precipitations in-between nano-crystalline domains. Here, we focus on super-stoichiometric TiB₂₊z thin films, varying the stoichiometry from TiB₂.₀₄ to TiB₄.₄₂ (B: 67–82 at.%). The tissue phase fraction and thickness is mainly governed by the B content and corresponding deposition conditions. A decreasing tissue phase width from ≈ 3–1 nm leads to an increasing critical stress intensity factor KIC of ≈ 40%.

Research facilities:

Röntgenzentrum
Universitäre Service-Einrichtung für Transmissionselektronenmikroskopie

Project title:

Oberflächentechnik von hochbeanspruchten Präzisionskomponenten: CDL-SEC (Christian Doppler Forschungsgesellschaft)

Research Areas:

Materials Characterization: 15%
Surfaces and Interfaces: 15%
Structure-Property Relationsship: 70%

Science Branch:

2100 - Nanotechnologie: 10%
2030 - Maschinenbau: 10%
2050 - Werkstofftechnik: 80%

License:

CC BY-NC 4.0