Prefractionation of LiCl from concentrated seawater/salt lake brines by electrodialysis with monovalent selective ion exchange membranes

Exploring the lithium resources in concentrated seawater/salt lake brine could provide necessary support for the sustainable development in future. Selective-electrodialysis (S-ED, equipped with monovalent selective ion-exchange membranes) is considered as an effective way to reduce the ratio of magnesium to lithium in concentrated seawater/salt lake brines. However, the effectiveness of the prefractionation of lithium chloride from brine is not clearly investigated, because both seawater and salt lake brines are complex mixtures. Nowadays, only simple systems with binary or ternary cations system have been investigated. Based on a clean production process for the utilization of concentrated seawater/salt lake brine, the prefractionation of LiCl from concentrated seawater/salt lake brines by S-ED was investigated in this work. From the concentrated seawater experiments, it is beneficial to improve the R-Li (recovery ratio of Li+) at a higher voltage, but an excessively high working voltage is adverse to the preliminary separation between Li+ and Mg2+; a bigger V-C/V-D (initial volume ratio of concentrating and desalting solution, V-D = 2.5 L in this paper) is favorable to increase R-Li and reduce E-SEC (specific energy consumption of Li+). At the optimal voltage of 7 V and V-C/V-D of 0.6, the mole ratio of LiCI: MgCl2: MgSO4 increased from 1: 2.227: 2.463 to 1: 1.461: 0.085. For the salt lake brines, the optimal voltage for the LiCI prefractionation in the selected brine system was 10 V, which had a higher R-Li of 76.45% and an appropriate E-SEC of 0.66 kWh/(mol Li). Finally, the parameters of R-Li, E-SEC and separation effect of LiCI were discussed for the salt lakes of West Taijinar, East Taijinar and Yiliping in China. It is found that the East Taijinar salt lake brine was more suitable to obtain LiCI at a lower E-SEC. (C) 2018 Elsevier Ltd. All rights reserved.