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Organic Radical-Boosted Ionic Conductivity in Redox Polymer Electrolyte for Advanced Fiber-Shaped Energy Storage Devices

Jeong-Gil Kim, Jaehyoung Ko, Hyung‐Kyu Lim, Yerin Jo, Hayoung Yu, Min Woo Kim, Min Ji Kim, Hyeon Su Jeong, Jinwoo Lee, Yongho Joo, Nam Dong Kim

2025Nano-Micro Letters9 citationsDOIOpen Access PDF

Abstract

Abstract Fiber-shaped energy storage devices (FSESDs) with exceptional flexibility for wearable power sources should be applied with solid electrolytes over liquid electrolytes due to short circuits and leakage issue during deformation. Among the solid options, polymer electrolytes are particularly preferred due to their robustness and flexibility, although their low ionic conductivity remains a significant challenge. Here, we present a redox polymer electrolyte (HT_RPE) with 4-hydroxy-2,2,6,6-tetramethylpiperidine-1-oxyl (HT) as a multi-functional additive. HT acts as a plasticizer that transforms the glassy state into the rubbery state for improved chain mobility and provides distinctive ion conduction pathway by the self-exchange reaction between radical and oxidized species. These synergetic effects lead to high ionic conductivity (73.5 mS cm −1 ) based on a lower activation energy of 0.13 eV than other redox additives. Moreover, HT_RPE with a pseudocapacitive characteristic by HT enables an outstanding electrochemical performance of the symmetric FSESDs using carbon-based fiber electrodes (energy density of 25.4 W h kg −1 at a power density of 25,000 W kg −1 ) without typical active materials, along with excellent stability (capacitance retention of 91.2% after 8,000 bending cycles). This work highlights a versatile HT_RPE that utilizes the unique functionality of HT for both the high ionic conductivity and improved energy storage capability, providing a promising pathway for next-generation flexible energy storage devices.

Topics & Concepts

ElectrolyteIonic conductivityMaterials scienceEnergy storageElectrochemistrySupercapacitorChemical engineeringConductivityRedoxIonic liquidCapacitancePower densityElectrodeIonic bondingNanotechnologyIonChemistryOrganic chemistryCatalysisPhysicsPower (physics)MetallurgyEngineeringQuantum mechanicsPhysical chemistryAdvanced battery technologies researchAdvanced Battery Materials and TechnologiesSupercapacitor Materials and Fabrication
Organic Radical-Boosted Ionic Conductivity in Redox Polymer Electrolyte for Advanced Fiber-Shaped Energy Storage Devices | Litcius