A comparative study on Arc- and vacuum induction-melting for Ti_16.6Zr_16.6Hf_16.6Co₁₀Ni₂₀Cu₂₀ high entropy shape memory Alloy Production

verfasst von: Christian Hinte, Andrea Fantin, Khemais Barienti, Sebastian Herbst, Jan Frenzel, Gunther Eggeler, Hans Jürgen Maier
Abstract: Arc-melting (AM) as a primary method for casting high entropy alloys (HEAs) ensures rapid alloy screening with minimal material input, high cost-effectiveness, and high cooling rates. However, the limitations of AM on a laboratory scale, particularly its constrained sample size and the necessity for remelting steps to ensure homogeneity, hampers thorough mechanical and functional testing of bulk materials. Therefore, this study features a comparative analysis between AM and vacuum induction-melting (VIM) techniques for High Entropy Shape Memory Alloys (HE-SMAs) production, focusing on the senary alloy Ti_16.6Zr_16.6Hf_16.6Co₁₀Ni₂₀Cu₂₀, known for its potential functional applications and high sensitivity to material inhomogeneity. The alloy’s composition, including high-melting point elements like Hf, Ti and Zr, makes it a well-suited candidate for assessing the capabilities of VIM in producing homogeneous bulk materials. The employment of binary pre-alloys in both AM and VIM processes reduced the necessity for remelting steps and ensured better initial quality for subsequent heat treatments. A homogenization treatment at 900 °C for 100 h of an AM-produced senary alloy showed only slight improvements compared to the same alloy produced via VIM, largely due to the slow diffusion of the larger Hf and Zr atoms from the dendrites into the solid solution. This suggests that VIM can achieve comparable levels of homogenization in substantially less time than required for AM-treated samples. The findings finally indicate that by using VIM, when combined with binary pre-alloys, one achieves more homogeneous alloys with reduced heat-treatment time, making it a viable method for HE-SMA production.
Organisationseinheit(en): Institut für Werkstoffkunde
Externe Organisation(en): Bundesanstalt für Materialforschung und -prüfung (BAM)
Typ: Artikel
Journal: Discover Materials
Band: 4
Publikationsdatum: 30.11.2024
Publikationsstatus: Elektronisch veröffentlicht (E-Pub)
Peer-reviewed: Ja
ASJC Scopus Sachgebiete: Werkstoffwissenschaften (sonstige), Biomaterialien, Elektronische, optische und magnetische Materialien, Metalle und Legierungen
Elektronische Version(en): https://doi.org/10.1007/s43939-024-00134-1 (Zugang: Offen)

BibTeX

@article{6cdea8f14ef24885848b94054e1be235,
title = "A comparative study on Arc- and vacuum induction-melting for Ti16.6Zr16.6Hf16.6Co10Ni20Cu20 high entropy shape memory Alloy Production",
abstract = "Arc-melting (AM) as a primary method for casting high entropy alloys (HEAs) ensures rapid alloy screening with minimal material input, high cost-effectiveness, and high cooling rates. However, the limitations of AM on a laboratory scale, particularly its constrained sample size and the necessity for remelting steps to ensure homogeneity, hampers thorough mechanical and functional testing of bulk materials. Therefore, this study features a comparative analysis between AM and vacuum induction-melting (VIM) techniques for High Entropy Shape Memory Alloys (HE-SMAs) production, focusing on the senary alloy Ti16.6Zr16.6Hf16.6Co10Ni20Cu20, known for its potential functional applications and high sensitivity to material inhomogeneity. The alloy{\textquoteright}s composition, including high-melting point elements like Hf, Ti and Zr, makes it a well-suited candidate for assessing the capabilities of VIM in producing homogeneous bulk materials. The employment of binary pre-alloys in both AM and VIM processes reduced the necessity for remelting steps and ensured better initial quality for subsequent heat treatments. A homogenization treatment at 900 °C for 100 h of an AM-produced senary alloy showed only slight improvements compared to the same alloy produced via VIM, largely due to the slow diffusion of the larger Hf and Zr atoms from the dendrites into the solid solution. This suggests that VIM can achieve comparable levels of homogenization in substantially less time than required for AM-treated samples. The findings finally indicate that by using VIM, when combined with binary pre-alloys, one achieves more homogeneous alloys with reduced heat-treatment time, making it a viable method for HE-SMA production.",
keywords = "Arc-melting (AM), High-entropy alloys (HEAs), Shape memory alloys (SMAs), Vacuum induction-melting (VIM), X-Ray diffraction (XRD)",
author = "Christian Hinte and Andrea Fantin and Khemais Barienti and Sebastian Herbst and Jan Frenzel and Gunther Eggeler and Maier, {Hans J{\"u}rgen}",
note = "Publisher Copyright: {\textcopyright} The Author(s) 2024.",
year = "2024",
month = nov,
day = "30",
doi = "10.1007/s43939-024-00134-1",
language = "English",
volume = "4",
journal = "Discover Materials",
issn = "2730-7727",
publisher = "Discover",
number = "1",
}

A comparative study on Arc- and vacuum induction-melting for Ti16.6Zr16.6Hf16.6Co10Ni20Cu20 high entropy shape memory Alloy Production

A comparative study on Arc- and vacuum induction-melting for Ti_16.6Zr_16.6Hf_16.6Co₁₀Ni₂₀Cu₂₀ high entropy shape memory Alloy Production