Litcius/Paper detail

Strong Lewis Acid–Base and Weak Hydrogen Bond Synergistically Enhancing Ionic Conductivity of Poly(ethylene oxide)@SiO<sub>2</sub> Electrolytes for a High Rate Capability Li-Metal Battery

Zhong Xu, Tao Yang, Xiang Chu, Hai Su, Zixing Wang, Ningjun Chen, Bingni Gu, Hepeng Zhang, Hepeng Zhang, Weili Deng, Haitao Zhang, Haitao Zhang, Weiqing Yang

2020ACS Applied Materials & Interfaces128 citationsDOI

Abstract

Solid-state composite polymer electrolytes (CPEs) usually suffer from intrinsic low ionic conductivity and a solid–solid interface, badly inhibiting their widespread commercial application in all-solid-state Li-metal battery (ASSLMB) energy storage. Herein, a synergetic strategy using strong Lewis acid–base and weak hydrogen bonds was employed for self-assembly in situ construction of three-dimensional (3D) network-structured poly(ethylene oxide) (PEO) and SiO2 CPEs (PEO@SiO2). Ascribed to this synergistically rigid–flexible coupling dynamic strategy, a harmonious incorporation of monodispersed SiO2 nanoparticles into PEO could remarkably reduce crystallinity of PEO, significantly enhancing the ionic conductivity (∼1.1 × 10–4 S cm–1 at 30 °C) and dramatically facilitating solid electrolyte interface stabilization (electrochemical stability window > 4.8 V at 90 °C). Moreover, the PEO@SiO2-based ASSLMBs possess excellent rate capability over a wide temperature range (∼105 mA h g–1 under 2 C at 90 °C), high temperature cycling capacity (retaining 90 mA h g–1 after 100 cycles at 90 °C), and high specific capacity (146 mA h g–1 under 0.3 C at 90 °C). Unambiguously, these high ionic conductivity CPEs along with excellent flexibility and safety can be one of the most promising candidates for high-performance ASSLMBs, evidently revealing that this synergistically rigid–flexible coupling dynamic strategy will open up a way to exploit the novel high ionic conductivity solid-state electrolytes.

Topics & Concepts

Materials scienceElectrolyteIonic conductivityEthylene oxideMetalConductivityInorganic chemistryBattery (electricity)OxideBase (topology)Lewis acids and basesIonic bondingHydrogenHydrogen bondChemical engineeringMoleculeIonOrganic chemistryCatalysisPhysical chemistryPolymerComposite materialElectrodeChemistryMetallurgyCopolymerPower (physics)EngineeringMathematicsQuantum mechanicsMathematical analysisPhysicsAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesAdvanced Battery Technologies Research