Enhancing the radiation- and oxidation-resistance of Cr-based coatings via structure regulation and composition optimization
Enhancing the radiation- and oxidation-resistance of Cr-based coatings via structure regulation and composition optimization
Cr coatings, as protective coatings of Zr-alloy fuel claddings, inevitably suffer from irradiation damage before they would possibly run into the accident condition. This study evaluates the radiation and oxidation tolerance of three Cr-based coatings with different microstructures (Cr, CrAlSi, and CrAlSiN) through He2+ ion irradiation and 1200 °C steam oxidation. The Cr and CrAlSi coatings experienced significant structural degradation, characterized by He bubble aggregation and amplified Kirkendall effects at elevated temperatures. In contrast, the irradiated CrAlSiN coating maintained structural integrity without measurable irradiation hardening. Following annealing at 800 °C for 30 min, approximately 40 % of injected He atoms were released, indicating a “self-healing” mechanism. The mechanism is attributed to uniformly distributed, low-density channels that act as sinks and release paths for irradiation-induced defects. Density functional theory simulations suggest that N atoms promote significant rearrangement of ions surrounding the free volume, inhibiting the formation of sites capable of trapping He atoms. Moreover, the CrAlSiN coating exhibited superior oxidation resistance compared to the Cr and CrAlSi coatings, even under high-temperature steam conditions. Notably, the irradiated CrAlSiN sample displayed a significantly thinner oxide scale compared to the pristine one (almost half), owing to a more protective oxide scale and rapid outward diffusion of Cr, Al, and Si through nanochannel veins. These findings illuminate the effects of structure and composition on irradiation and oxidation behavior in Cr-based coatings, offering insights for developing
new-generation accident-tolerance fuel coatings for Zr-alloy claddings.
153-169
Wang, Renda
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Daghbouj, Nabil
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Yu, Ping
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Meng, Fanping
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Li, Peng
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Cammarata, Antonio
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Li, Bingsheng
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Bábor, P.
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Polcar, Tomas
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Qing He, Huang
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Ge, Fangfang
61181109-851a-475e-a392-0e5326f4aba1
22 October 2024
Wang, Renda
f2f6181f-c72a-4097-a8b9-46f09b2ab043
Daghbouj, Nabil
44a697ed-e6b7-4f28-ab80-e6a4d1bbc7c2
Yu, Ping
96236e0b-ebe0-4eef-968f-1b34f97f47d2
Meng, Fanping
7e802f36-0eb7-44b4-99e7-866b0603c194
Li, Peng
26066bbb-96d8-488a-a5e0-287c5b47b8e7
Cammarata, Antonio
d9f02172-7364-4d80-a32b-03d2d7970257
Li, Bingsheng
ea2e7a47-e7eb-45b5-80ac-62566a975e24
Bábor, P.
ef59023c-5cc4-4a34-939b-967d95b96569
Polcar, Tomas
c669b663-3ba9-4e7b-9f97-8ef5655ac6d2
Qing He, Huang
8c9c971b-4e7a-4470-9cde-1ed7587ee2d2
Ge, Fangfang
61181109-851a-475e-a392-0e5326f4aba1
Wang, Renda, Daghbouj, Nabil, Yu, Ping, Meng, Fanping, Li, Peng, Cammarata, Antonio, Li, Bingsheng, Bábor, P., Polcar, Tomas, Qing He, Huang and Ge, Fangfang
(2024)
Enhancing the radiation- and oxidation-resistance of Cr-based coatings via structure regulation and composition optimization.
Journal of Materials Science & Technology, 218, .
(doi:10.1016/J.JMST.2024.08.051).
Abstract
Cr coatings, as protective coatings of Zr-alloy fuel claddings, inevitably suffer from irradiation damage before they would possibly run into the accident condition. This study evaluates the radiation and oxidation tolerance of three Cr-based coatings with different microstructures (Cr, CrAlSi, and CrAlSiN) through He2+ ion irradiation and 1200 °C steam oxidation. The Cr and CrAlSi coatings experienced significant structural degradation, characterized by He bubble aggregation and amplified Kirkendall effects at elevated temperatures. In contrast, the irradiated CrAlSiN coating maintained structural integrity without measurable irradiation hardening. Following annealing at 800 °C for 30 min, approximately 40 % of injected He atoms were released, indicating a “self-healing” mechanism. The mechanism is attributed to uniformly distributed, low-density channels that act as sinks and release paths for irradiation-induced defects. Density functional theory simulations suggest that N atoms promote significant rearrangement of ions surrounding the free volume, inhibiting the formation of sites capable of trapping He atoms. Moreover, the CrAlSiN coating exhibited superior oxidation resistance compared to the Cr and CrAlSi coatings, even under high-temperature steam conditions. Notably, the irradiated CrAlSiN sample displayed a significantly thinner oxide scale compared to the pristine one (almost half), owing to a more protective oxide scale and rapid outward diffusion of Cr, Al, and Si through nanochannel veins. These findings illuminate the effects of structure and composition on irradiation and oxidation behavior in Cr-based coatings, offering insights for developing
new-generation accident-tolerance fuel coatings for Zr-alloy claddings.
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Accepted/In Press date: 26 August 2024
e-pub ahead of print date: 22 October 2024
Published date: 22 October 2024
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Local EPrints ID: 511055
URI: http://eprints.soton.ac.uk/id/eprint/511055
PURE UUID: 08464280-ee6e-4a8a-bbee-c181763f8127
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Date deposited: 29 Apr 2026 16:51
Last modified: 30 Apr 2026 01:44
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Contributors
Author:
Renda Wang
Author:
Nabil Daghbouj
Author:
Ping Yu
Author:
Fanping Meng
Author:
Peng Li
Author:
Antonio Cammarata
Author:
Bingsheng Li
Author:
P. Bábor
Author:
Huang Qing He
Author:
Fangfang Ge
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