Güler, EnverOthman, Nur HidayatiKabay, NalanGuler, EnverChemical Engineering2024-07-052024-07-052022100167-82992191-023510.1515/revce-2020-00702-s2.0-85110300315https://doi.org/10.1515/revce-2020-0070https://hdl.handle.net/20.500.14411/1994OTHMAN, NUR HIDAYATI/0000-0002-8396-2947; Güler, Enver/0000-0001-9175-0920Reverse electrodialysis (RED) is among the evolving membrane-based processes available for energy harvesting by mixing water with different salinities. The chemical potential difference causes the movement of cations and anions in opposite directions that can then be transformed into the electrical current at the electrodes by redox reactions. Although several works have shown the possibilities of achieving high power densities through the RED system, the transformation to the industrial-scale stacks remains a challenge particularly in understanding the correlation between ion-exchange membranes (IEMs) and the operating conditions. This work provides an overview of the RED system including its development and modifications of IEM utilized in the RED system. The effects of modified membranes particularly on the psychochemical properties of the membranes and the effects of numerous operating variables are discussed. The prospects of combining the RED system with other technologies such as reverse osmosis, electrodialysis, membrane distillation, heat engine, microbial fuel cell), and flow battery have been summarized based on open-loop and closed-loop configurations. This review attempts to explain the development and prospect of RED technology for salinity gradient power production and further elucidate the integrated RED system as a promising way to harvest energy while reducing the impact of liquid waste disposal on the environment.eninfo:eu-repo/semantics/openAccessenergy harvestingintegrated systemion-exchange membrane (IEM)reverse electrodialysis (RED)salinity gradient power (SGP)ReviewQ2388921958WOS:000739624300001