On the role of ultrasound and mechanical stirring for iodide adsorption by calcined layered double hydroxides

• Uptake capacity is dependent on their Mg/Al molar ratio and initial interlayer anion.
• The uptake capacity is strongly affected by the material textural properties.
• Adsorption assisted by ultrasound increases the iodide removal efficiency.
• Mass transfer was better promoted by use of ultrasound.
• Iodide adsorption capacity of hydrotalcites was better fitted by Langmuir model.

Improving the adsorption of long-term radioactive species in the underground disposal of waste waters from nuclear reactors is a key issue. The natural metal oxides or hydroxides underground have the low retention ability of anionic species. Here, calcined Mg/Al LDHs were used as adsorbents. The influence on the adsorption capacity of different intercalated guest anions (carbonate (CO32 −) and nitrate (NO3−)) in the parent LDH was investigated, along with the effect of ultrasonication. Two Mg/Al molar ratios (3/1 and 2/1) were compared. Adsorption capacity was strongly affected by material textural properties, and the carbonate LDH-derived mixed oxides showed the largest adsorption capacity. Mixed oxides with an Mg/Al molar ratio equal to 3 presented higher iodide adsorption due to their lower charge density. The adsorption assisted by ultrasound increased iodide removal efficiency by reducing internal diffusion limitation. Two models were used to determine adsorption capacity: Langmuir and Freundlich. The iodide adsorption was best fitted by the Langmuir equilibrium model.

Figure optionsDownload as PowerPoint slide