Abstract
Oxygen-containing functional groups tend to induce a strong interaction between solid adsorbents and iodine molecules, yet have not been systematically investigated. Herein, on the basis of a series of nitric acid-treated graphene oxide (GO) with different contents of oxygen functional groups for iodine adsorption, it was found that the iodine uptake capacity is proportionate to the oxygen content and the diversities of oxygen-containing groups. The density functional theory (DFT) calculation results also suggest that oxygen-containing groups result in strong interactions between iodine molecules and the adsorbents through a covalent bond-forming process, among which -OH groups possess a higher adsorption energy averagely. Such theoretical and experimental work deepens our understanding of the effects of oxygen functional groups on iodine adsorption and provides novel ideas for future design and synthesis of high-performance solid adsorbents for radioactive iodine.
Highlights
Nuclear power has made great contributions to the society due to the high-power density and low greenhouse-gas emission [1,2]
After HNO3 treatment by a simple hydrothermal reaction, the surfaces of all the samples obtained at different temperatures (100 ◦ C, 110 ◦ C and 120 ◦ C) become rough (Figure 1b–d,f–h)
With the temperature further increasing to higher levels, the cracks and wrinkles on the surface (e.g., graphene oxide (GO)-120) became more evident
Summary
Nuclear power has made great contributions to the society due to the high-power density and low greenhouse-gas emission [1,2]. Loads of adsorbents including silica [8], chalcogen-based aerogels [9], activated carbon [10], zeolites [11,12] and porous frameworks [13,14,15,16]
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