Layer dissolution in accumulative roll bonded bulk Zr/Nb multilayers under heavy-ion irradiation

Layer dissolution in accumulative roll bonded bulk Zr/Nb multilayers under heavy-ion irradiation

In this work, the heavy-ion irradiation behavior of bulk zirconium-niobium multilayered composites was investigated up to large doses. Multilayers with an average individual layer thicknesses ranging between 15 and 80 nm were synthesized by accumulative roll bonding technique. The irradiation was pe...

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Bibliographic Details
Published in:Journal of nuclear materials Vol. 557
Main Authors: Radhakrishnan, Madhavan, Kombaiah, Boopathy, Bachhav, Mukesh N., Nizolek, Thomas Joseph, Wang, Yongqiang Q., Knezevic, Marko, Mara, Nathan Allan, Anderoglu, O.
Format: Journal Article
Language:English
Published: United States Elsevier 25-09-2021
Subjects:
Accumulative roll bonding (ARB)
Forced chemical mixing
Ion irradiation
MATERIALS SCIENCE
Radiation-induced mixing (RIM)
Thermal spikes
Zr/Nb multilayers
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Summary:In this work, the heavy-ion irradiation behavior of bulk zirconium-niobium multilayered composites was investigated up to large doses. Multilayers with an average individual layer thicknesses ranging between 15 and 80 nm were synthesized by accumulative roll bonding technique. The irradiation was performed with a defocused 7 MeV Zr2+ ion beam at 500 °C. The maximum dose achieved was ~145 dpa at the depth of ~1.5 μm from the irradiated surface. Sub-surface microstructural damage and the chemical redistribution were characterized by transmission electron microscopy and energy dispersive spectroscopy, respectively. Irrespective of the layer thicknesses, the irradiation condition caused layer instability and the extent of damage varied with the dose levels. Doses lesser than ~60 dpa caused layer fragmentation and greater than ~60 dpa resulted in layer dissolution. The chemical mixing of layers occur to a depth of ~1 μm, consuming multiple bi-layer periods. Despite the elevated irradiation temperature (500 °C) and a slightly positive heat of mixing (+6 kJ/mol), no phase separation was observed and single-phase was retained in the mixed region. The results demonstrate that chemical mixing was facilitated by the liquid phase miscibility of Zr and Nb, which propelled the interdiffusion within the thermal spikes towards mixing.
Bibliography:USDOE Office of Science (SC)
AC07-05ID14517; 89233218CNA000001; NRC-HQ-60-17-G-0007; NE0008656
INL/JOU-21-62309-Rev000; LA-UR-21-24055
USNRC
USDOE Office of Nuclear Energy (NE)
USDOE National Nuclear Security Administration (NNSA)
ISSN:0022-3115
1873-4820