Q. Li scite author profile

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.

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Mechanical behavior of structurally gradient nickel alloy

Ding

et al. 2018

Acta Materialia

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Tailoring the strength and ductility of T91 steel by partial tempering treatment

et al. 2019

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Ultra-strong nanotwinned Al–Ni solid solution alloys with significant plasticity

Zhang

Xue

et al. 2018

Nanoscale

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In situ studies on irradiation resistance of nanoporous Au through temperature-jump tests

Fan

et al. 2018

Acta Materialia

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Q. Li

In situ heavy ion irradiation studies of nanopore shrinkage and enhanced radiation tolerance of nanoporous Au

Mechanical behavior of structurally gradient nickel alloy

Tailoring the strength and ductility of T91 steel by partial tempering treatment

Ultra-strong nanotwinned Al–Ni solid solution alloys with significant plasticity

In situ studies on irradiation resistance of nanoporous Au through temperature-jump tests

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