Nuclear Materials and Energy (Oct 2022)
Efficient capture of radioactive iodine by Ag-attached silica gel and its kinetics
Abstract
In order to absorb the radioactive iodine produced during the reprocessing of spent fuel in nuclear power plants, in this study, the self-made silver content of 2–8 % Ag-attached silica gel was used as the adsorbent to adsorb radioactive iodine. Through dynamic adsorption method discussed with Ag-attached silica gel by the total flow at the inlet, the packing layer height in adsorption column under the factors such as temperature, humidity and adsorption of gaseous iodine adsorption effect. The experimental conclusions show that the saturated adsorption capacity is almost not affected by the different inlet flow rate, and the mass transfer resistance of the adsorption column increases under the condition of small inlet flow rate, resulting in longer adsorption time and more saturated adsorption. The height of Ag-attached silica gel packing layer in the adsorption column has little effect on the mass transfer resistance, and its saturated adsorption capacity increases with the increase of packing layer height. The adsorption effect is almost the same under different humidity. Under the same other conditions, by isothermal adsorption of Ag-attached silica gel at different temperatures, it can be found that the adsorption effect of Ag-attached silica gel at 150 °C is the best, which is consistent with the literature referred to. Through the kinetic simulation of silica gel with several different adsorption models, it can be found that the Yoon-Nelson model can well fit the dynamic adsorption process of gaseous iodine on silica gel with silver content of 2–8 %. The dynamic adsorption of iodine on silica gel shows that the adsorption capacity of gaseous iodine on silica gel is 40.60–238.83 mg/g. Moreover, Ag-attached silica gel has stable properties and lower cost than other sorbents. It is a promising adsorbent and can be widely used for radioactive iodine generated in the post-processing of spent fuel.
