Spinodally reinforced W-Cr fusion armour

Alexander J. Knowles; Tat Yiu Spencer Cheung; Kan Ma; Russel Dodds; Samuel A. Humphry-Baker; Felipe F. Morgado; Shyam S. Katnagallu; Eduardo Saiz; Baptiste Gault; Christopher D. Hardie; David Dye

doi:10.1016/j.apmt.2024.102430

Spinodally reinforced W-Cr fusion armour

Alexander J. Knowles^*
, Tat Yiu Spencer Cheung
, Kan Ma
, Russel Dodds
, Samuel A. Humphry-Baker
, Felipe F. Morgado
, Shyam S. Katnagallu
, Eduardo Saiz
, Baptiste Gault
, Christopher D. Hardie
, David Dye

^*Corresponding author for this work

Metallurgy and Materials

Research output: Contribution to journal › Article › peer-review

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Abstract

Here, we introduce a discontinuous spinodal reinforcement strategy in the novel candidate plasma facing material (PFM) of tungsten-chromium alloys. Thermal ageing of a W-34wt%Cr alloy at 1250 °C causes nano-scale lamellae 200–600 nm to form heterogeneously from grain boundaries, which progressively grow into the matrix fully, then coarsen to 1–2 µm after 100 h. The dual-phase microstructure confers exceptional high temperature compressive strength, maintaining 900 MPa at 1000 °C - double that of polycrystalline tungsten. Further, the chromium alloying promotes a dense oxide scale that confers a 2 orders of magnitude improvement in resistance against oxidation at 1000 °C compared to W, which is an important consideration for PFMs under loss of vacuum accident conditions. The dual-phase W-Cr alloy concept's combination of high strength and oxidation resistance represents a new scalable alternative to tungsten, with wide scope for further alloying and process optimisation.

Original language	English
Article number	102430
Number of pages	7
Journal	Applied Materials Today
Volume	41
Early online date	12 Sept 2024
DOIs	https://doi.org/10.1016/j.apmt.2024.102430
Publication status	Published - Dec 2024

Keywords

Fusion energy
Microstructure design
Spinodal decomposition
Tungsten alloys

ASJC Scopus subject areas

General Materials Science

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10.1016/j.apmt.2024.102430Licence: Creative Commons: Attribution (CC BY)

KnowlesA2024SpinodallyFinal published version, 7.3 MBLicence: Creative Commons: Attribution (CC BY)

Bcc-superalloys: Engineering Resilience to Extreme Environments
Knowles, S. (Principal Investigator)
Medical Research Council
1/11/20 → 30/06/25
Project: Research Councils
Titanium, steel and tungsten superalloys: Engineering fracture and irradiation resistance RF\201819\18\158
Knowles, S. (Principal Investigator)
Royal Academy of Engineering
1/10/19 → 30/09/20
Project: Research

Cite this

@article{da2432770ba14c92b11af32e396dce27,

title = "Spinodally reinforced W-Cr fusion armour",

abstract = "Here, we introduce a discontinuous spinodal reinforcement strategy in the novel candidate plasma facing material (PFM) of tungsten-chromium alloys. Thermal ageing of a W-34wt\%Cr alloy at 1250 °C causes nano-scale lamellae 200–600 nm to form heterogeneously from grain boundaries, which progressively grow into the matrix fully, then coarsen to 1–2 µm after 100 h. The dual-phase microstructure confers exceptional high temperature compressive strength, maintaining 900 MPa at 1000 °C - double that of polycrystalline tungsten. Further, the chromium alloying promotes a dense oxide scale that confers a 2 orders of magnitude improvement in resistance against oxidation at 1000 °C compared to W, which is an important consideration for PFMs under loss of vacuum accident conditions. The dual-phase W-Cr alloy concept's combination of high strength and oxidation resistance represents a new scalable alternative to tungsten, with wide scope for further alloying and process optimisation.",

keywords = "Fusion energy, Microstructure design, Spinodal decomposition, Tungsten alloys",

author = "Knowles, \{Alexander J.\} and Cheung, \{Tat Yiu Spencer\} and Kan Ma and Russel Dodds and Humphry-Baker, \{Samuel A.\} and Morgado, \{Felipe F.\} and Katnagallu, \{Shyam S.\} and Eduardo Saiz and Baptiste Gault and Hardie, \{Christopher D.\} and David Dye",

year = "2024",

month = dec,

doi = "10.1016/j.apmt.2024.102430",

language = "English",

volume = "41",

journal = "Applied Materials Today",

issn = "2352-9407",

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TY - JOUR

T1 - Spinodally reinforced W-Cr fusion armour

AU - Knowles, Alexander J.

AU - Cheung, Tat Yiu Spencer

AU - Ma, Kan

AU - Dodds, Russel

AU - Humphry-Baker, Samuel A.

AU - Morgado, Felipe F.

AU - Katnagallu, Shyam S.

AU - Saiz, Eduardo

AU - Gault, Baptiste

AU - Hardie, Christopher D.

AU - Dye, David

PY - 2024/12

Y1 - 2024/12

N2 - Here, we introduce a discontinuous spinodal reinforcement strategy in the novel candidate plasma facing material (PFM) of tungsten-chromium alloys. Thermal ageing of a W-34wt%Cr alloy at 1250 °C causes nano-scale lamellae 200–600 nm to form heterogeneously from grain boundaries, which progressively grow into the matrix fully, then coarsen to 1–2 µm after 100 h. The dual-phase microstructure confers exceptional high temperature compressive strength, maintaining 900 MPa at 1000 °C - double that of polycrystalline tungsten. Further, the chromium alloying promotes a dense oxide scale that confers a 2 orders of magnitude improvement in resistance against oxidation at 1000 °C compared to W, which is an important consideration for PFMs under loss of vacuum accident conditions. The dual-phase W-Cr alloy concept's combination of high strength and oxidation resistance represents a new scalable alternative to tungsten, with wide scope for further alloying and process optimisation.

AB - Here, we introduce a discontinuous spinodal reinforcement strategy in the novel candidate plasma facing material (PFM) of tungsten-chromium alloys. Thermal ageing of a W-34wt%Cr alloy at 1250 °C causes nano-scale lamellae 200–600 nm to form heterogeneously from grain boundaries, which progressively grow into the matrix fully, then coarsen to 1–2 µm after 100 h. The dual-phase microstructure confers exceptional high temperature compressive strength, maintaining 900 MPa at 1000 °C - double that of polycrystalline tungsten. Further, the chromium alloying promotes a dense oxide scale that confers a 2 orders of magnitude improvement in resistance against oxidation at 1000 °C compared to W, which is an important consideration for PFMs under loss of vacuum accident conditions. The dual-phase W-Cr alloy concept's combination of high strength and oxidation resistance represents a new scalable alternative to tungsten, with wide scope for further alloying and process optimisation.

KW - Fusion energy

KW - Microstructure design

KW - Spinodal decomposition

KW - Tungsten alloys

UR - https://www.scopus.com/pages/publications/85203656377

U2 - 10.1016/j.apmt.2024.102430

DO - 10.1016/j.apmt.2024.102430

M3 - Article

AN - SCOPUS:85203656377

SN - 2352-9407

VL - 41

JO - Applied Materials Today

JF - Applied Materials Today

M1 - 102430

ER -

Spinodally reinforced W-Cr fusion armour

Abstract

Keywords

ASJC Scopus subject areas

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Projects

Bcc-superalloys: Engineering Resilience to Extreme Environments

Titanium, steel and tungsten superalloys: Engineering fracture and irradiation resistance RF\201819\18\158

Cite this