Journal
MATERIALS SCIENCE AND ENGINEERING A-STRUCTURAL MATERIALS PROPERTIES MICROSTRUCTURE AND PROCESSING
Volume 850, Issue -, Pages -Publisher
ELSEVIER SCIENCE SA
DOI: 10.1016/j.msea.2022.143558
Keywords
Nanostructured multilayers; Interfaces; Radiation hardening; Mechanical behavior
Categories
Funding
- National Natural Science Foundation of China [92163201, U2067219, 52001247]
- Na-tional Key Research and Development Program of China [2017YFA0700701]
- 111 Project 2.0 of China [BP2018008]
- Fundamental Research Funds for the Central Universities [xtr022019004]
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Nanostructured metallic multilayers (NMMs) have been widely studied as efficient accident-tolerant fuel (ATF) materials. In this work, Cr75Al25/Zr (CA/Zr) NMMs with different layer thicknesses were prepared and subjected to He+ implantation. The results showed that the interface of the NMMs changed from crystalline/crystalline to crystalline/amorphous when the thickness decreased to 25 nm, accompanied by a transition from strengthening to softening behavior. The study also found significant irradiation hardening in the NMMs, which was attributed to the interactions between He bubbles and dislocations, as well as the increased back-stress hardening at different thicknesses.
As an efficient strategy to design accident-tolerant fuel (ATF) materials, nanostructured metallic multilayers (NMMs) have attracted significant research interest. In this work, Cr75Al25/Zr (CA/Zr) NMMs were prepared with equal individual layer thickness h spanning from 5 to 75 nm, and subjected to He+ implantation with a total fluence of 1 x 10(17) ions cm(-2 )at room temperature. With decreasing h, the interface changed from crystalline/ crystalline to crystalline/amorphous along with size-driven strengthening to softening behavior of CA/Zr NMMs at the critical thickness h = 25 nm. The size-dependent hardness consists well with the evolution of the back stress with respect to h, which is elucidated by the statistical dislocation absorption propensity by the interface. Moreover, notable irradiation hardening emerges in the CA/Zr NMMs, which is caused by He bubble-dislocation interactions at large h and by the cooperation of He bubble hardening and increased back-stress hardening at small h. The hardness of both as-deposited and irradiated CA/Zr NMMs was quantitatively explained by dislocation models operative at different length scales.
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