Comparative microstructural investigations of Ti-Al-N thin films alloyed with Y or Nb

Research output: ThesisDiploma Thesis

Bibtex - Download

@phdthesis{71911c6a692044cdaba1ac7dc5cb4465,
title = "Comparative microstructural investigations of Ti-Al-N thin films alloyed with Y or Nb",
abstract = "To reduce weight and increase efficiency, heavy alloys in structural components like turbines are to be replaced by light-weight alloys, such as TiAl-based alloys, which very often lack in oxidation and wear resistance especially at temperatures above 750°C. Consequently, effective wear protection is required, e.g. deposition with coatings, having high mechanical properties and thermal stability. This work represents an attempt to improve the established protective coating Ti-Al-N, in this respective by the addition of the transition metals yttrium or niobium. Therefore, utilizing a plasma-assisted physical vapour deposition (PVD) process and TiAl-targets alloyed with 0, 2, 4, and 8 at.% of Y or Nb, Ti-Al-M-N-coatings were prepared, where M represents Y or Nb. By means of in-situ high temperature X-ray-diffraction, transmission electron microscopy, nanoindentation and simultaneous thermal analysis, the individual influence of Y and Nb on microstructure, mechanical properties and thermal stability, was investigated. It is shown, that with increasing Y-contents the structure of Ti-Al-N changes from single-phase cubic to binary-phase cubic-hexagonal or single-phase hexagonal, whereas the investigated Nb-alloyed Ti-Al-N-coatings have a single-phase cubic structure. The changed microstructure for the Y-containing coatings results in a decrease in hardness and indentation modulus with increasing Y-content, whereas with the addition of Nb to the single-phase cubic Ti-Al-N-films the hardness and indentation modulus increases. During thermal treatment, both coatings systems Ti-Al-Y-N and Ti-Al-Nb-N exhibit increasing thermal stability with respect to decomposition processes of their metastable phases with increasing Y- respectively Nb-content. Consequently, these coating systems are promising for high-temperature applications.",
keywords = "Ti-Al-N Y Nb spinodale Entmischung TEM in-situ HT-XRD Nanoindentation STA Mikrostruktur, Ti-Al-N Y Nb spinodal decomposition TEM in-situ HT-XRD nanoindentation STA microstructure",
author = "Richard Rachbauer",
note = "embargoed until null",
year = "2008",
language = "English",
type = "Diploma Thesis",

}

RIS (suitable for import to EndNote) - Download

TY - THES

T1 - Comparative microstructural investigations of Ti-Al-N thin films alloyed with Y or Nb

AU - Rachbauer, Richard

N1 - embargoed until null

PY - 2008

Y1 - 2008

N2 - To reduce weight and increase efficiency, heavy alloys in structural components like turbines are to be replaced by light-weight alloys, such as TiAl-based alloys, which very often lack in oxidation and wear resistance especially at temperatures above 750°C. Consequently, effective wear protection is required, e.g. deposition with coatings, having high mechanical properties and thermal stability. This work represents an attempt to improve the established protective coating Ti-Al-N, in this respective by the addition of the transition metals yttrium or niobium. Therefore, utilizing a plasma-assisted physical vapour deposition (PVD) process and TiAl-targets alloyed with 0, 2, 4, and 8 at.% of Y or Nb, Ti-Al-M-N-coatings were prepared, where M represents Y or Nb. By means of in-situ high temperature X-ray-diffraction, transmission electron microscopy, nanoindentation and simultaneous thermal analysis, the individual influence of Y and Nb on microstructure, mechanical properties and thermal stability, was investigated. It is shown, that with increasing Y-contents the structure of Ti-Al-N changes from single-phase cubic to binary-phase cubic-hexagonal or single-phase hexagonal, whereas the investigated Nb-alloyed Ti-Al-N-coatings have a single-phase cubic structure. The changed microstructure for the Y-containing coatings results in a decrease in hardness and indentation modulus with increasing Y-content, whereas with the addition of Nb to the single-phase cubic Ti-Al-N-films the hardness and indentation modulus increases. During thermal treatment, both coatings systems Ti-Al-Y-N and Ti-Al-Nb-N exhibit increasing thermal stability with respect to decomposition processes of their metastable phases with increasing Y- respectively Nb-content. Consequently, these coating systems are promising for high-temperature applications.

AB - To reduce weight and increase efficiency, heavy alloys in structural components like turbines are to be replaced by light-weight alloys, such as TiAl-based alloys, which very often lack in oxidation and wear resistance especially at temperatures above 750°C. Consequently, effective wear protection is required, e.g. deposition with coatings, having high mechanical properties and thermal stability. This work represents an attempt to improve the established protective coating Ti-Al-N, in this respective by the addition of the transition metals yttrium or niobium. Therefore, utilizing a plasma-assisted physical vapour deposition (PVD) process and TiAl-targets alloyed with 0, 2, 4, and 8 at.% of Y or Nb, Ti-Al-M-N-coatings were prepared, where M represents Y or Nb. By means of in-situ high temperature X-ray-diffraction, transmission electron microscopy, nanoindentation and simultaneous thermal analysis, the individual influence of Y and Nb on microstructure, mechanical properties and thermal stability, was investigated. It is shown, that with increasing Y-contents the structure of Ti-Al-N changes from single-phase cubic to binary-phase cubic-hexagonal or single-phase hexagonal, whereas the investigated Nb-alloyed Ti-Al-N-coatings have a single-phase cubic structure. The changed microstructure for the Y-containing coatings results in a decrease in hardness and indentation modulus with increasing Y-content, whereas with the addition of Nb to the single-phase cubic Ti-Al-N-films the hardness and indentation modulus increases. During thermal treatment, both coatings systems Ti-Al-Y-N and Ti-Al-Nb-N exhibit increasing thermal stability with respect to decomposition processes of their metastable phases with increasing Y- respectively Nb-content. Consequently, these coating systems are promising for high-temperature applications.

KW - Ti-Al-N Y Nb spinodale Entmischung TEM in-situ HT-XRD Nanoindentation STA Mikrostruktur

KW - Ti-Al-N Y Nb spinodal decomposition TEM in-situ HT-XRD nanoindentation STA microstructure

M3 - Diploma Thesis

ER -