Separation and detection of lanthanides by capillary electrophoresis

• Published in: Journal of analytical chemistry (New York, N.Y.) Vol. 67; no. 4; pp. 378 - 385
• Main Authors: Nilchi, A., Edalat, M., Taghiof, M., Rasouli Garmarodi, S.
• Format: Journal Article
• Language: English
• Published: Dordrecht SP MAIK Nauka/Interperiodica 01.04.2012; Springer
• Subjects: Analysis; Analytical Chemistry; Chemistry; Chemistry and Materials Science; Electric fields; Electrophoresis; Nuclear industry; electrical field; pH; ionic strength; simulation; capillary electrophoresis; lanthanides
• ISSN: 1061-9348; 1608-3199
• DOI: 10.1134/S1061934812040156

Due to the importance of application of lanthanides in various industries especially the nuclear ones, and the advantages of capillary electrophoresis method in separation of metal cations, this research was carried out in order to investigate the separation potential of lanthanides using capillary electrophoresis via simulation method at laboratory scale. Since the properties of various types of lanthanides are very similar, the separation of lanthanides using the usual approaches was not possible. Thus, the separation of lanthanides was devised upon partial, competing complexation in order to differentiate their properties. Salicylic acid was firstly used as the primary UV-absorbing ligand, whereas formic, acetic, lactic, tartaric and citric acids, which showed no absorption in UV-spectrum and had weaker complexes in comparison to salicylic acid, were used as auxiliary ligands. Upon the results of spectrometry, the wave length of 210 nm was selected for detecting lanthanides. The properties and stability of lanthanides were examined and furthermore acetic and citric acids were selected as auxiliary ligands. The simulation was carried out with respect to the transport phenomena in the unsteady state. The ion species dissociation was found to be directly dependent upon the concentration, and was also used in complexation. The results of simulation showed that the diffusion control of H + and homogenizing electrical field promoted separation quality. The separation conditions were optimized by using the simulation results as well as the tests obtained. In order to optimize the experimental conditions, variable factors such as voltage, injection time, pH, temperature and ionic strength were examined. Also, methanol was used as dissolving modifier as well as noise reducer on the base line. Sodium nitrate was used as ionic strength controller and sucrose for increasing viscosity which optimized separation quality.