Abstract
High energy particle radiations induce severe microstructural damage in metallic materials. Nanoporous materials with a giant surface-to-volume ratio may alleviate radiation damage in irradiated metallic materials as free surface are defect sinks. Here we show, by using in situ Kr ion irradiation in a transmission electron microscope at room temperature, that nanoporous Au indeed has significantly improved radiation tolerance comparing with coarse-grained, fully dense Au. In situ studies show that nanopores can absorb and eliminate a large number of radiation-induced defect clusters. Meanwhile, nanopores shrink (self-heal) during radiation, and their shrinkage rate is pore size dependent. Furthermore, the in situ studies show dose-rate-dependent diffusivity of defect clusters. This study sheds light on the design of radiation-tolerant nanoporous metallic materials for advanced nuclear reactor applications.
Highlights
Counterparts[30,31,32]
We report on the dose-rate-dependent defect global and instantaneous diffusivities in np Au, which has not been studied in np Ag previously
As-prepared cg Au and np Au were both transparent to the electron beam
Summary
Counterparts[30,31,32]. There are extensive studies on mechanical properties of np metals[33,34,35,36]. Ex situ study on np Au under 400 keV Ne++ ion irradiation shows that defect accumulation depends on dose rate[37]. Vacancies have enough time to aggregate and form SFTs. Previous in situ study on np Ag shows the removal of various types of defect clusters, including SFTs, small dislocation loops and large dislocation segments, by the free surface in np Ag under 1 MeV Kr++ ion irradiation[32]. We present in situ Kr ion irradiation studies on cg and np Au. The migration of defect clusters and their elimination by free surfaces are captured by in situ video. Nanovoids shrink due to the absorption of defect clusters by nanovoids during irradiation in np Au, and their shrinkage rate depends on pore size. The outstanding irradiation tolerance of np Au has important implications for the design of advanced np materials under extreme radiation environment
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