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In Situ Reconstruction of the Ceramic Particle Surface Boosting High-Performance and Ultrathin Hybrid Solid-State Electrolyte

Shilei Chang, Jialong Cao, Aonan Wang, Mochun Zhang, Fan Yang, Jing Xu, Yanqing Lai, Faping Zhong, Mengran Wang, Zhian Zhang

2025ACS Nano11 citationsDOI

Abstract

Garnet-based solid electrolytes endow lithium-based batteries with higher safety and energy density as compared to those of conventional lithium-ion batteries. The dry process is a promising fabrication method to eliminate energy-intensive drying and solvent recovery steps, preventing degradation of garnet-based electrolytes during the production of garnet-based solid electrolytes. However, owing to the poor ion conduction of Li 2 CO 3 formed on ceramic particles, garnet-based composite solid electrolytes synthesized by the dry processing method normally exhibit unsatisfactory ionic conductivity. Herein, we propose an interface-reconstructing strategy to in situ convert the insulating Li 2 CO 3 into a lithium salt-rich layer, which is beneficial to further form a highly Li + conductive eutectic bridge between ceramic particles. Based on the optimization, an ultrathin ceramic electrolyte membrane (20 μm) exhibits an excellent Li + conductivity of 5.56 × 10 –4 S cm –1 at 30 °C and high safety. After 500 cycles at a 1C rate, the capacity retention rate of the assembled quasi-solid-state lithium metal battery is 80.2%, much better than similar work reported previously. Taken together, this facile bridge strategy can effectively improve the electrochemical performance, which facilitates the mass production of ceramic electrolyte membranes.

Topics & Concepts

Materials scienceCeramicBoosting (machine learning)In situElectrolyteNanotechnologySolid-stateParticle (ecology)NanoparticleChemical engineeringElectrodeEngineering physicsComposite materialComputer scienceChemistryPhysical chemistryArtificial intelligenceEngineeringOrganic chemistryOceanographyGeologyAdvancements in Battery MaterialsAdvanced Battery Materials and TechnologiesThermal Expansion and Ionic Conductivity
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