Dry-Processable Polymer Electrolytes for Solid Manufactured Batteries
Jiying Yang, Zhang Cao, Yuwei Chen, Xueqing Liu, Yizhi Xiang, Yuan Yuan, Xin Cui, Yumin Xia, Shuohan Huang, Zhe Qiang, Kun Fu, Jianming Zhang
Abstract
Designing a solid-state electrolyte that satisfies the operating requirements of solid-state batteries is key to solid-state battery applications. The consensus is that solid-state electrolytes need to allow fast ion transport, while providing better interfacial compatibility and mechanical tolerance. Herein, a simple but effective strategy is proposed, combining hard and soft component polymer systems, to exploit a solid polymer electrolyte (SPE) with a 3D network via an in situ graft polymerization. The 3D structure is constructed by a hard cellulose nanocrystal (CNC) as the skeleton and a soft polyacrylonitrile (PAN) as the filler through a dry-processing method. The reported systems have several advantages, including ease of processing, only requiring using an exceedingly small amount of solvent, light weight (ρ = 1.2 g cm –3 ), excellent mechanical stability (tensile strength of 9.5 MPa), and high ionic conductivity (3.9 × 10 –4 S cm –1, 18 °C) and migration number ( t Li + = 0.8). In particular, the high conductivity is enabled: the efficient Li + transportation path constructed between CNC-PAN powders and abundant sulfonate radicals and hydroxyl groups on the CNC surface acts as the bridge of Li + transition. When the CNCs are grafted onto the PAN polymer, the dipole–dipole interaction between the nitrile groups of the PAN and the hydroxyl groups of the CNCs can help to improve the mechanical stability and ionic conductivity of the SPE. Moreover, a tightly formed interface between SPE and LiFePO 4 (LFP)/carbon black/SPE cathode can be achieved in an assembled solid-state battery by hot pressing, thus further enhancing the battery’s performance.