Understanding helium induced nanostructure formation. This project addresses the interaction dynamics of high-flux helium particles with materials that drives surface nanowire growth. These dynamics are important to nuclear reactor materials and to developing new nanotechnology materials for high energy density lithium-ion battery anodes and water splitting catalysts. Through model and experiment, this project expects to generate new knowledge of processes that drive sub-surface nano-bubble form ....Understanding helium induced nanostructure formation. This project addresses the interaction dynamics of high-flux helium particles with materials that drives surface nanowire growth. These dynamics are important to nuclear reactor materials and to developing new nanotechnology materials for high energy density lithium-ion battery anodes and water splitting catalysts. Through model and experiment, this project expects to generate new knowledge of processes that drive sub-surface nano-bubble formation and surface nanowire growth in materials exposed to helium particles. This project will result in improved understanding of material degradation during nuclear reactor operation and will make a new contribution to high-value manufacturing capabilities for next generation energy systems.Read moreRead less