This study focuses on the development of energy-efficient resin wafer electrodeionization, of which resins in the dilute compartment is immobilized and fabricated into wafer by Hot-Press. Such changes could make the resins uniformly-distributed in both vertical and horizontal direction, which can enhance separation efficiency of RW-EDI for brackish water desalination and decrease energy consumption. The characteristics of resin wafer materials before and after hot-pressed can be detected via SEM and FT-IR. The application of SEM could help to obtain the information of surface topography and composition of resin wafer. The functional groups of the resin wafer could be detected by FT-IR to capture the peak at the specific wavenumber. By comparing FT-IT images of resin wafer before and after treating wastewater, the functional groups (SO32- and Quaternary Ammonium) participating in adsorption of ions could be determined. The investigation of effect of applied voltage, feed flow rate and influent concentration on performance of RE-EDI suggests that the removal efficiency of RW-EDI could reach more than 99% in 2 hours, indicating it very effective in treating brackish water. On the other hand, applied voltage has a more drastic influence on removal efficiency than feed flow rate. As for current efficiency, it could be significantly influenced by voltage, feed flow rate and influent concentration, of which higher voltage, lower flow rate and lower influent concentration corresponds to a lower current efficiency. Vice versa. It suggests that the ion removal rate will increase with both increased applied voltage and feed flow rate. On the one hand, the increased voltage enhances the driving force as static force to migrate ions from dilute compartment into concentrate compartment. On the other hand, the increased feed flow rate improves the mass transfer between mixed-resin bed and ions to enhance adsorption of ions, and the retention time of flow decreases, both of which accelerate the removal of ions. Above all, the removal kinetics of RW-EDI fits a pseudo first-order model well, of which the reaction rate constant is a function of applied voltage and feed flow rate. The energy consumption of this study for treating a NaCl solution with TDS of 5,000 mg/L are 0.493 ~ 2.361 kWh/m3, corresponding to productivity of 16 ~ 42 L/(m2*hr) with removal efficiency larger than 90% and energy efficiency of 21 ~ 48%. By comparison of reverse osmosis (RO) which is most applicable, its energy consumption for treating NaCl solution of the same concentration is 1.2 ~ 1.5 kWh/m3, of which the energy efficiency is only 12 ~ 15% and removal efficiency of 80%, indicating that RW-EDI is a promising desalination technology. By response surface methodology giving the limitation of energy consumption and productivity, the optimal operation conditions for treating brackish water with 5,000 mg/L NaCl are 9.25 V and 490 mL/min, corresponding to the best achievable energy consumption and productivity of 1.397 kWh/m3 and 33 L/(m2*hr), respectively. To assess the life cycle impacts of RW-EDI on environment with RO as business-as-usual scenario, it presents a less life-cycle impacts of RW-EDI on environment than RO. The utilization of concentrate wastewater from EDI in capturing CO2 via RPB shows a significant increase of captured CO2 compared with tap water, providing an approach to deal with wastewater from EDI.