Karakoc, EzgiGuler, EnverChemical Engineering2024-07-052024-07-052022102077-037510.3390/membranes120302572-s2.0-85125497703https://doi.org/10.3390/membranes12030257https://hdl.handle.net/20.500.14411/1806Güler, Enver/0000-0001-9175-0920; Karakoc, Ezgi/0000-0002-2992-9089The development of the most effective, suitable and economic ion-exchange membranes is crucial for reverse electrodialysis (RED)-the most widely studied process to harvest salinity gradient energy from mixing seawater and river water. RED utilizes two types of membranes as core elements, namely cation exchange membranes (CEM) and anion exchange membranes (AEM). Since the preparation of AEMs is more complex compared to CEMs, the design and development of anion exchange membranes have been the focus in this study. Homogeneous AEMs based on two types of polyepichlorohydrin (PECH) with different chlorine amounts (PECH-H, 37 wt% and PECH-C, 25 wt%) were synthesized, and first-time benchmarking of the membrane properties was conducted. In addition to physicochemical membrane properties, some instrumental analyses such as SEM, FTIR and DSC were investigated to characterize these anion-exchange membranes. Based on the results, although the PECH-H-type membrane had enhanced ion-exchange properties, PECH-C-based anion-exchange membranes exhibited a higher power density of 0.316 W/m(2) in a lab-scale RED system. Evidently, there is room for the development of new types of PECH-C-based AEMs with great potential for energy generation in the RED process.eninfo:eu-repo/semantics/openAccessanion-exchange membranepolyepichlorohydrinreverse electrodialysissalinity gradient powerblue energyComparison of Physicochemical Properties of Two Types of Polyepichlorohydrin-Based Anion Exchange Membranes for Reverse ElectrodialysisArticleQ3123WOS:00077414130000135323732