Abstract

Instead of commercial lithium-ion batteries (LIBs) using organic liquid electrolytes, all-solid-state lithium-ion batteries (ASSBs) employing solid electrolytes (SEs) are promising for applications in high-energy–density power applications and electric vehicles due to their potential for improving safety and achieving high capacity. Although remarkable progress in SEs has been achieved and has resulted in high ionic conductivity, which now reaches values comparable to those of liquid electrolytes, the typical use of a slurry process for the fabrication of conventional ASSBs inevitably causes harmful reactions between sulfide materials and polar solvents. Here, we studied the efficient infiltration process of SE slurry into conventional composite LIB electrodes (NCM622) for achieving high-energy-density ASSBs via a scalable solution-based fabrication process. Two methods are proposed to ensure that SE materials are evenly distributed and sufficiently infiltrated into the porous structures of LIB electrodes. The LPSCl SE solutions were effectively infiltrated into the electrodes at higher processing temperatures and the temperature was subsequently optimized at above the boiling point of the ethanol solvent due to the dynamic motion of SE molecules via a convective flow during solvent vaporization. Moreover, the porous LIB composite electrodes with a mixture of active materials of different particle sizes formed and filled capillary pores resulting in a high electrode density. The LPSCl SE-infiltrated NCM622 electrodes that used this strategy could remarkably improve the initial discharge capacity of ASSBs to as high as 177 mAh/g. These ASSBs also showed excellent performance even at high loading values (about 17 mg/cm2), making them competitive with LIBs using conventional liquid electrolytes.

Highlights

  • Instead of commercial lithium-ion batteries (LIBs) using organic liquid electrolytes, all-solid-state lithium-ion batteries (ASSBs) employing solid electrolytes (SEs) are promising for applications in high-energy–density power applications and electric vehicles due to their potential for improving safety and achieving high capacity

  • The LIB electrodes were dipped in the as-prepared LPSCl solution, and samples were dried in an oven followed by thermal treatment at 180 °C under vacuum in order to solidify the SE films as well as fully remove the residual solvent

  • The fabrication of SE-infiltrated NCM622 electrodes was completed by pressing the samples under load of 700 MPa to induce intimate contact between active materials and the SE and better connection by increasing the density of the films

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Summary

Introduction

Instead of commercial lithium-ion batteries (LIBs) using organic liquid electrolytes, all-solid-state lithium-ion batteries (ASSBs) employing solid electrolytes (SEs) are promising for applications in high-energy–density power applications and electric vehicles due to their potential for improving safety and achieving high capacity. Remarkable progress in SEs has been achieved and has resulted in high ionic conductivity, which reaches values comparable to those of liquid electrolytes, the typical use of a slurry process for the fabrication of conventional ASSBs inevitably causes harmful reactions between sulfide materials and polar solvents. Inorganic SEs in ASSBs have the same operating principle as conventional organic LEs, and many types of SEs have been developed in the past several years, including garnet-type, NASICON-type, perovskite-type, LISICONtype, sulfide-type, and argyrodite-type ­SEs9 Among those various types of SEs, sulfide-type, and argyrodite-type SEs are very promising in terms of their large scale solution processability, deformable mechanical properties, high ionic conductivities, and excellent electrochemical ­performance[10]. This poor ionic and electrical contact inevitably causes large interfacial resistance

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