Sorption Profile of Low Specific Activity Mo on Nanoceria-Based Sorbents for the Development of Tc Generators: Kinetics, Equilibrium, and Thermodynamic Studies.

Mo/Tc generators play a significant role in supplying Tc for diagnostic interventions in nuclear medicine. However, the applicability of using low specific activity (LSA) Mo asks for sorbents with high sorption capacity. Herein, this study aims to evaluate the sorption behavior of LSA Mo towards several CeO nano-sorbents developed in our laboratory. These nanomaterials were prepared by wet chemical precipitation (CP) and hydrothermal (HT) approaches. Then, they were characterized using XRD, BET, FE-SEM, and zeta potential measurements. Additionally, we evaluated the sorption profile of carrier-added (CA) Mo onto each material under different experimental parameters. These parameters include pH, initial concentration of molybdate solution, contact time, and temperature. Furthermore, the maximum sorption capacities were evaluated. The results reveal that out of the synthesized CeO nanoparticles (NPs) materials, the sorption capacity of HT-1 and CP-2 reach 192 ± 10 and 184 ± 12 mg Mo·g, respectively. For both materials, the sorption kinetics and isotherm data agree with the Elovich and Freundlich models, respectively. Moreover, the diffusion study demonstrates that the sorption processes can be described by pore diffusion (for HT-synthesis route 1) and film diffusion (for CP-synthesis route 2). Furthermore, the thermodynamic parameters indicate that the Mo sorption onto both materials is a spontaneous and endothermic process. Consequently, it appears that HT-1 and CP-2 have favorable sorption profiles and high sorption capacities for CA-Mo. Therefore, they are potential candidates for producing a Mo/Tc radionuclide generator by using LSA Mo.