Abstract
Organic redox compounds represent an emerging class of active materials for organic redox-flow batteries (RFBs), which are highly desirable for sustainable electrical energy storage. The structural diversity of organic redox compounds helps in tuning the electrochemical properties as compared to the case of their inorganic counterparts. However, the structural diversity makes the design and identification of redox-active organic materials difficult because it is challenging to achieve appropriate redox potential, solubility and stability together, which are the major concerns regarding the practical applicability of these materials to RFBs. Herein, we report the design, synthesis, and application of viologen molecules as anolyte materials for organic RFBs that are compatible with Li-ion electrolytes. Structural screening assisted by density functional theory (DFT) calculations suggests that the (CH2)5CH3-substituted viologen molecule exhibits reduction potential as low as 2.74 V vs. Li/Li+, good structural stability due to effective charge delocalization within the two pyridinium rings, and a solubility of up to 1.3 M in carbonate-based electrolytes. When paired with a 2,2′:6′,2′′-terpyridine–iron complex catholyte, the cell shows a high discharge voltage of 1.3–1.5 V with coulombic efficiency > 98% and energy efficiency > 84%. Both the anolyte and catholyte materials are built from earth-abundant elements and can be produced with high yields; thus, they may represent a promising choice for sustainable electrical energy storage.
Highlights
Sustainable electric energy storage systems are important as they enable full utilization of renewable electricity generated from intermittent energy sources such as wind and sun; redox ow batteries (RFBs) have been considered as one of the most important electric energy storage systems for upcoming largescale applications.[1]
Viologen derivatives are of particular interest and have been utilized as an anolyte material in aqueous organic redox-flow batteries (RFBs) recently.[14]
The reversibility of electron transfer reactions, redox potential, solubility and energy gap (Eg) of the highest occupied molecular orbital (HOMO)–LUMO of viologen derivatives should be strongly related to the nitrogen substituents, which have been rst screened by density functional theory (DFT) calculations
Summary
Sustainable electric energy storage systems are important as they enable full utilization of renewable electricity generated from intermittent energy sources such as wind and sun; redox ow batteries (RFBs) have been considered as one of the most important electric energy storage systems for upcoming largescale applications.[1]. Recent studies have demonstrated the promise of using redox-active organic materials as viable alternatives towards a new generation of RFBs;[5] the merits of using organic materials arise from the structural diversity and tunability of electrochemical properties in addition to material sustainability and abundance
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