DATASET: Radiation-grafted anion-exchange membranes for reverse electrodialysis: a comparison of N,N,N',N'-tetramethylhexene-1,6-diamine crosslinking (amination stage) and divinylbenzene crosslinking (grafting stage)

<b>Data files:</b><br><b>D1TA05166K DATA1 (AS PLOTTED).xlsx</b><br>This file contains the final data used to plot all of the Figures in the article.<br><b>Further data files will be uploaded in due course.</b><i>If you require any other data related to the article, please e-mail j.varcoe@surrey.ac.uk</i><br><b><b><br></b>Main article abstract:</b>Radiation-grafted anion-exchange membranes (RG-AEM) are being developed to evaluate a range of chemistries that have relevance to a variety of electrochemical applications including reverse electrodialysis (RED) salinity gradient power. RG-AEMs are typically fabricated using an electron-beam activated (peroxidated) polymer substrate film. These activated films are first grafted with a monomer, such as vinylbenzyl chloride (VBC) and then reacted with a variety of tertiary amines to yield the desired RG-AEMs. The amination process forms covalently bound quaternary ammonium (QA) head-groups that allow the RG-AEMs to conduct anions such as Cl⁻. RG-AEMs are of interest as they exhibit high conductivities (100 mS cm^-1 at elevated temperatures when containing Cl⁻ anions). However, the current generation of RG-AEMs have two main Achilles’ heels: (1) they exhibit low permselectivities; and (2) they exhibit a high degree of swelling in water. Introducing covalent crosslinking into ion-exchange membranes is a well-known strategy to overcome these issues but it often comes with a price – a significantly lowered conductivity (raised <i>in situ</i> resistance). Therefore, the level of crosslinking must be carefully optimised. RG-AEMs can be primarily crosslinked using two methods: (1) introduction of a divinyl monomer into the monomer mixture used during grafting; or (2) introduction of a diamine agent into the amination process. This study looks into both methods where either divinylbenzene (DVB) is added into the grafting mixture or <i>N</i>,<i>N</i>,<i>N'</i>,<i>N'</i>-tetramethylhexene-1,6-diamine (TMHDA) is added into the amination mixture. We show that on the balance of two application-relevant properties (resistances in aqueous NaCl (0.5 mol dm^-3) solution and permselectivity), the diamine crosslinking method is the most effective for RG-AEMs being used in RED cells.