Phase stability of V- based multi-principal element alloysCitation formats

  • External authors:
  • Paul J. Barron
  • Alexander W. Carruthers
  • Huw Dawson
  • Nick G. Jones

Standard

Phase stability of V- based multi-principal element alloys. / Barron, Paul J.; Carruthers, Alexander W.; Dawson, Huw; Rigby, Maxwell T. P.; Haigh, Sarah; Jones, Nick G.; Pickering, Ed J.

In: Materials Science and Technology, 09.04.2022.

Research output: Contribution to journalArticlepeer-review

Harvard

Barron, PJ, Carruthers, AW, Dawson, H, Rigby, MTP, Haigh, S, Jones, NG & Pickering, EJ 2022, 'Phase stability of V- based multi-principal element alloys', Materials Science and Technology.

APA

Barron, P. J., Carruthers, A. W., Dawson, H., Rigby, M. T. P., Haigh, S., Jones, N. G., & Pickering, E. J. (Accepted/In press). Phase stability of V- based multi-principal element alloys. Materials Science and Technology.

Vancouver

Barron PJ, Carruthers AW, Dawson H, Rigby MTP, Haigh S, Jones NG et al. Phase stability of V- based multi-principal element alloys. Materials Science and Technology. 2022 Apr 9.

Author

Barron, Paul J. ; Carruthers, Alexander W. ; Dawson, Huw ; Rigby, Maxwell T. P. ; Haigh, Sarah ; Jones, Nick G. ; Pickering, Ed J. / Phase stability of V- based multi-principal element alloys. In: Materials Science and Technology. 2022.

Bibtex

@article{20890f9566e344138b36badf9084bda2,
title = "Phase stability of V- based multi-principal element alloys",
abstract = "The success of fusion power requires alloys with good mechanical properties and the ability to withstand extreme thermal and irradiation conditions without prohibitive levels of activation or structural degradation. Body centred cubic multi-principal component alloys, V-Cr-Mn and Ti-V-Cr-Mn have shown promising high temperature stability at 1200 C. For the alloys to be suitable for use in nuclear fusion reactors, they must be stable across a wide range of temperatures relevant to fusion applications. Here, we assess alloy microstructural stability in these systems following long-term heat treatments at various temperatures. Encouragingly, most of the alloys showed no significant change in microstructure across all temperatures. This contrasts with many other multi-principal component alloys, which develop complex microstructures after exposure to intermediate temperatures.",
author = "Barron, {Paul J.} and Carruthers, {Alexander W.} and Huw Dawson and Rigby, {Maxwell T. P.} and Sarah Haigh and Jones, {Nick G.} and Pickering, {Ed J.}",
year = "2022",
month = apr,
day = "9",
language = "English",
journal = "Materials Science and Technology",
issn = "0267-0836",
publisher = "Taylor & Francis",

}

RIS

TY - JOUR

T1 - Phase stability of V- based multi-principal element alloys

AU - Barron, Paul J.

AU - Carruthers, Alexander W.

AU - Dawson, Huw

AU - Rigby, Maxwell T. P.

AU - Haigh, Sarah

AU - Jones, Nick G.

AU - Pickering, Ed J.

PY - 2022/4/9

Y1 - 2022/4/9

N2 - The success of fusion power requires alloys with good mechanical properties and the ability to withstand extreme thermal and irradiation conditions without prohibitive levels of activation or structural degradation. Body centred cubic multi-principal component alloys, V-Cr-Mn and Ti-V-Cr-Mn have shown promising high temperature stability at 1200 C. For the alloys to be suitable for use in nuclear fusion reactors, they must be stable across a wide range of temperatures relevant to fusion applications. Here, we assess alloy microstructural stability in these systems following long-term heat treatments at various temperatures. Encouragingly, most of the alloys showed no significant change in microstructure across all temperatures. This contrasts with many other multi-principal component alloys, which develop complex microstructures after exposure to intermediate temperatures.

AB - The success of fusion power requires alloys with good mechanical properties and the ability to withstand extreme thermal and irradiation conditions without prohibitive levels of activation or structural degradation. Body centred cubic multi-principal component alloys, V-Cr-Mn and Ti-V-Cr-Mn have shown promising high temperature stability at 1200 C. For the alloys to be suitable for use in nuclear fusion reactors, they must be stable across a wide range of temperatures relevant to fusion applications. Here, we assess alloy microstructural stability in these systems following long-term heat treatments at various temperatures. Encouragingly, most of the alloys showed no significant change in microstructure across all temperatures. This contrasts with many other multi-principal component alloys, which develop complex microstructures after exposure to intermediate temperatures.

M3 - Article

JO - Materials Science and Technology

JF - Materials Science and Technology

SN - 0267-0836

ER -