Dual-channel membrane capacitive deionization based on asymmetric ion adsorption for continuous water desalination

Capacitive deionization (CDI) systems are well known for their ability to efficiently desalinate water by adsorbing ions onto two electrodes through the application of an electrical potential difference. In this study, we report a continuous desalination device composed of a novel dual-channel CDI cell architecture containing three ion exchange membranes (CAC-MCDI). The adsorption of ions and electrode regeneration from the desorption ions were performed separately in the two channels and enabled continuous water desalination by the application of an intermittent voltage reversal. Additionally, the novel cell architecture performed an electrodialysislike process when the adsorption of ions on the electrode reached saturation, demonstrating a synergistic effect. For the first time, a CDI system is modified for the asymmetric adsorption of cations and anions, to reveal the effect of the migration rate difference of ions. Fully making use of ion diffusion differences as well as the synergistic effect can effectively improve the performance of the system and surprisingly increase the charge efficiency above 100%. The parameters for the desalination process were first optimized by response surface methodology (RSM), which predicted that the salt removal efficiency and charge efficiency could reach 69.29% and 103.60%, respectively. Both the experimental results and the predicted values from the model indicated that asymmetric ion adsorption capabilities of CAC-MCDI allowed the system to achieve excellent performance and provide continuous water desalination.

Automated summary

A novel dual-channel CDI cell architecture, CAC-MCDI, was reported in this study for continuous water desalination with a synergistic effect. By modifying a CDI system for the asymmetric adsorption of cations and anions, the system achieved excellent performance with a charge efficiency exceeding 100%. Optimized parameters using response surface methodology predicted salt removal efficiency and charge efficiency reaching 69.29% and 103.60%, respectively, demonstrating the capabilities of the CAC-MCDI system for continuous water desalination.