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Differentiating Design of Multifunctional Interfaces on Ceramic Solid Electrolytes for High-Performance Lithium-Air Batteries
25 Pages Posted: 30 Jan 2024 Publication Status: Published
Abstract
High-energy-density lithium (Li)–air cells have been considered a promising energy-storage system, but the liquid electrolyte-related safety and side-reaction problems seriously hinder their development. To address these above issues, solid-state Li–air batteries have been widely developed. However, many commonly-used solid electrolytes generally face huge interface impedance in Li–air cells and also show poor stability towards ambient air/Li electrodes. Herein, we fabricate a differentiating surface-regulated ceramic-based composite electrolyte (DSCCE) by constructing disparately LiI-containing polymethyl methacrylate (PMMA) coating and Poly(vinylidene fluoride-co-hexafluoropropylene) (PVDF-HFP) layer on both sides of Li1.5Al0.5Ge1.5(PO4)3 (LAGP). The cathode-friendly LiI/PMMA layer displays excellent stability towards O2- and also greatly reduces the decomposition voltage of discharge products in Li–air system. Additionally, the anode-friendly PVDF-HFP coating shows low-resistance properties towards anodes. Moreover, Li dendrite/passivation derived from liquid electrolyte-induced side reactions and air/I-attacking can be obviously suppressed by the uniform and compact composite framework. As a result, the DSCCE-based Li–air batteries possess high capacity/low voltage polarization (11837 mA h g-1/1.45 V under 500 mA g-1), good rate performance (capacity ratio under 1000 mA g-1/200 mA g-1 is 68.2 %) and long-term stable cell operation (300 cycles at 750 mA g-1 with 750 mAh g-1) in ambient air.
Keywords: Li-air batteries, Li1.5Al0.5Ge1.5(PO4)3, Polymers, Composite electrolyte, Ambient air
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