Study on the sorption and desorption behavior of La and Bi by bis(2-ethylhexyl)phosphate modified activated carbon.

The separation of Bi from its parent radionuclide Ac radionuclide generators has proven to be a challenge due to the limited performance of the current sorbents. This study evaluated the separation performance of La (as a surrogate for Ac) and Bi using bis(2-ethylhexyl)phosphate monofunctionalized activated carbon (HDEHP/AC). The potential applications of phosphate groups as active sites and the carbon structure as a sorbent support were confirmed and validated. Various factors, including pH values, salt concentration, halide ions, contact time, solid-to-liquid ratio, initial La/Bi concentration, and gamma irradiation were examined through batch sorption experiments in both single and binary systems. HDEHP/AC had a high sorption capacity for La electrostatic attraction, with the sorption data fitting well to the pseudo-second-order kinetic equation and Langmuir model. The sorption performance of La on HDEHP/AC was minimally affected as the NaCl/NaI concentrations increased at pH = 2, whereas the sorption capacity for Bi decreased significantly. Additionally, selective desorption of La and Bi was achieved using HNO and NaI solutions, respectively. These results backed up by a conceptual separation process point toward a potential use of these materials in a direct/inverse Ac/Bi radionuclide generator. Further optimization of the material and separation process will be required to bring this class of promising materials into an actual generator for medical applications.