A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments

O. El Atwani; H. T. Vo; M. A. Tunes; C. Lee; A. Alvarado; N. Krienke; J. D. Poplawsky; A. A. Kohnert; J. Gigax; W. Y. Chen; M. Li; Y. Q. Wang; J. S. Wróbel; D. Nguyen-Manh; J. K.S. Baldwin; O. U. Tukac; E. Aydogan; S. Fensin; E. Martinez

doi:10.1038/s41467-023-38000-y

A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments

O. El Atwani, H. T. Vo, M. A. Tunes, C. Lee, A. Alvarado, N. Krienke, J. D. Poplawsky, A. A. Kohnert, J. Gigax, W. Y. Chen, M. Li, Y. Q. Wang, J. S. Wróbel, D. Nguyen-Manh, J. K.S. Baldwin, O. U. Tukac, E. Aydogan, S. Fensin, E. Martinez

Los Alamos National Laboratory

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

12 Scopus citations

Abstract

In the quest of new materials that can withstand severe irradiation and mechanical extremes for advanced applications (e.g. fission & fusion reactors, space applications, etc.), design, prediction and control of advanced materials beyond current material designs become paramount. Here, through a combined experimental and simulation methodology, we design a nanocrystalline refractory high entropy alloy (RHEA) system. Compositions assessed under extreme environments and in situ electron-microscopy reveal both high thermal stability and radiation resistance. We observe grain refinement under heavy ion irradiation and resistance to dual-beam irradiation and helium implantation in the form of low defect generation and evolution, as well as no detectable grain growth. The experimental and modeling results—showing a good agreement—can be applied to design and rapidly assess other alloys subjected to extreme environmental conditions.

Original language	English
Article number	2516
Journal	Nature Communications
Volume	14
Issue number	1
DOIs	https://doi.org/10.1038/s41467-023-38000-y
State	Published - Dec 2023

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El Atwani, O., Vo, H. T., Tunes, M. A., Lee, C., Alvarado, A., Krienke, N., Poplawsky, J. D., Kohnert, A. A., Gigax, J., Chen, W. Y., Li, M., Wang, Y. Q., Wróbel, J. S., Nguyen-Manh, D., Baldwin, J. K. S., Tukac, O. U., Aydogan, E., Fensin, S., & Martinez, E. (2023). A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments. Nature Communications, 14(1), Article 2516. https://doi.org/10.1038/s41467-023-38000-y

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title = "A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments",

abstract = "In the quest of new materials that can withstand severe irradiation and mechanical extremes for advanced applications (e.g. fission & fusion reactors, space applications, etc.), design, prediction and control of advanced materials beyond current material designs become paramount. Here, through a combined experimental and simulation methodology, we design a nanocrystalline refractory high entropy alloy (RHEA) system. Compositions assessed under extreme environments and in situ electron-microscopy reveal both high thermal stability and radiation resistance. We observe grain refinement under heavy ion irradiation and resistance to dual-beam irradiation and helium implantation in the form of low defect generation and evolution, as well as no detectable grain growth. The experimental and modeling results—showing a good agreement—can be applied to design and rapidly assess other alloys subjected to extreme environmental conditions.",

author = "{El Atwani}, O. and Vo, {H. T.} and Tunes, {M. A.} and C. Lee and A. Alvarado and N. Krienke and Poplawsky, {J. D.} and Kohnert, {A. A.} and J. Gigax and Chen, {W. Y.} and M. Li and Wang, {Y. Q.} and Wr{\'o}bel, {J. S.} and D. Nguyen-Manh and Baldwin, {J. K.S.} and Tukac, {O. U.} and E. Aydogan and S. Fensin and E. Martinez",

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El Atwani, O, Vo, HT, Tunes, MA, Lee, C, Alvarado, A, Krienke, N, Poplawsky, JD, Kohnert, AA, Gigax, J, Chen, WY, Li, M, Wang, YQ, Wróbel, JS, Nguyen-Manh, D, Baldwin, JKS, Tukac, OU, Aydogan, E, Fensin, S & Martinez, E 2023, 'A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments', Nature Communications, vol. 14, no. 1, 2516. https://doi.org/10.1038/s41467-023-38000-y

TY - JOUR

T1 - A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments

AU - El Atwani, O.

AU - Vo, H. T.

AU - Tunes, M. A.

AU - Lee, C.

AU - Alvarado, A.

AU - Krienke, N.

AU - Poplawsky, J. D.

AU - Kohnert, A. A.

AU - Gigax, J.

AU - Chen, W. Y.

AU - Li, M.

AU - Wang, Y. Q.

AU - Wróbel, J. S.

AU - Nguyen-Manh, D.

AU - Baldwin, J. K.S.

AU - Tukac, O. U.

AU - Aydogan, E.

AU - Fensin, S.

AU - Martinez, E.

PY - 2023/12

Y1 - 2023/12

N2 - In the quest of new materials that can withstand severe irradiation and mechanical extremes for advanced applications (e.g. fission & fusion reactors, space applications, etc.), design, prediction and control of advanced materials beyond current material designs become paramount. Here, through a combined experimental and simulation methodology, we design a nanocrystalline refractory high entropy alloy (RHEA) system. Compositions assessed under extreme environments and in situ electron-microscopy reveal both high thermal stability and radiation resistance. We observe grain refinement under heavy ion irradiation and resistance to dual-beam irradiation and helium implantation in the form of low defect generation and evolution, as well as no detectable grain growth. The experimental and modeling results—showing a good agreement—can be applied to design and rapidly assess other alloys subjected to extreme environmental conditions.

AB - In the quest of new materials that can withstand severe irradiation and mechanical extremes for advanced applications (e.g. fission & fusion reactors, space applications, etc.), design, prediction and control of advanced materials beyond current material designs become paramount. Here, through a combined experimental and simulation methodology, we design a nanocrystalline refractory high entropy alloy (RHEA) system. Compositions assessed under extreme environments and in situ electron-microscopy reveal both high thermal stability and radiation resistance. We observe grain refinement under heavy ion irradiation and resistance to dual-beam irradiation and helium implantation in the form of low defect generation and evolution, as well as no detectable grain growth. The experimental and modeling results—showing a good agreement—can be applied to design and rapidly assess other alloys subjected to extreme environmental conditions.

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VL - 14

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 2516

ER -

A quinary WTaCrVHf nanocrystalline refractory high-entropy alloy withholding extreme irradiation environments

Abstract

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