Abstract
From the standpoint of material diversification and sustainability, the development of so-called “beyond lithium-ion” battery chemistries is important for the future of energy storage. Na, K, and Ca are promising as the basis for battery chemistries in that these elements are highly abundant. Here, a series of single-ion conducting polymer electrolytes (SIPEs) for Na, K, and Ca batteries are synthesized and investigated. The two classes of metal cation neutralized SIPEs compared are crosslinked poly(ethylene glycol) dimethacrylate-x-styrene sulfonate (PEGDMA-SS) and poly(tetrahydrofuran) diacrylate-x-4-styrenesulfonyl (trifluoromethylsulfonyl)imide (PTHFDA-STFSI); three cation types, three charge densities, and four swelling states are examined. The impact on conductivity of all of these parameters is studied, and in conjunction with small angle X-ray scattering (SAXS), it is found that promoting ion dissociation and preventing the formation of dense ionic aggregates facilitates ion transport. These results indicate many of the lessons learned from the Li SIPE literature can be translated to beyond Li chemistries. At 25 °C, the best performing Na/K and Ca exchanged polymers yield active cation conductivity on the order of 10−4 S/cm and 10−6 S/cm, respectively, for ethylene carbonate:propylene carbonate gelled SIPEs, and 10−5 S/cm and 10−7 S/cm, respectively, for glyme gelled SIPEs.
Highlights
Since the development of the lithium-ion rechargeable battery in the 1990s, there has been a revolution in consumer electronics
single-ion conducting polymer electrolytes (SIPEs) were more conductive than the PEGDMA-styrene sulfonate (SS) counterparts in the gel state, as the former had higher ion dissociation, lower ionic aggregation, and lower polymer–cation and polymer–solvent interactions
The effect of charge density was revealed to be dependent on polymer chemistry; when the additional ion content of high charge density polymers could be dissociated and did not contribute to reduced ion mobility via morphological changes induced in the polymer, the conductivity was improved
Summary
Since the development of the lithium-ion rechargeable battery in the 1990s, there has been a revolution in consumer electronics. Is akin toLi‐ion usinghas only a grid load‐leveling, thatstage promise harmful greenhouse hammer to build an entire house; the energy revolution will be realized when an energy storage been considered for and is in early stage use in all of these areas; this is akin to using only need is paired with a specific chemistry the application. Each unique rechargeable a hammer to build an entire house; thebest nextsuited energytorevolution will be realized when an energy storage need presents is paired its with a specific chemistry best suitedwith to the application. In certain situations where power density and gravimetric capacity are key, such as small electronics, Li battery technology may continue to dominate the market. Abundance of rechargeable batteryrelevant relevantLi, Li, Na, Na, Ca, in in seawater andand in the FigureFigure
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