Novel nanoarchitecture of 3D ion transfer channel containing nanocomposite solid polymer electrolyte membrane based on holey graphene oxide and chitosan biopolymer

“…The Li‐LiFePO 4 full cell shows stable cycling performance at 0.1 C (with a loading of 3 mg cm −2 ), and the specific capacity of the Li‐S full cell is still > 610 mAh g −1 at 60 °C after cycling for 300 cycles at 0.2 C. Similarly, Lu et al. [ 168 ] introduced graphene oxide into a polymer to create a flexible, self‐supporting, and ultrathin (80 um) SPE membrane. The novel three‐dimensional ionic transport paths in the SPE membrane, which are homogeneous and strongly interconnected, can facilitate ionic transport, and as a result, the RT ionic conductivity of SPE membrane is as high as 2.76 × 10 −3 S cm −1 , comparable to that of liquid electrolytes.…”

“…Although the solution casting method has been widely used for the large‐scale preparation of polymer‐based SSEs due to the simplicity and maturity of the process, the ability to incorporate a variety of additives as needed, the ease of preparing composite solid electrolytes with oxide/sulfide SSEs, and the ease of infiltration into porous and skeletal materials, the method has been prominent in CPEs in particular due to the integration of the advantages of each of the SPEs and inorganic SSEs. [ 170–172 ] There are five main structural designs studied, namely free‐standing SSE, [ 159–169 ] skeleton supporting SSE, [ 173–194 ] SSE with low tortuosity, [ 195–198 ] electrode‐supporting SSE [ 199–201 ] and in situ polymerization. [ 182,202–208 ] However, it is worth noting that the solution casting method is mainly based on SPE for the preparation and design of CSE, and the introduction of SPE will force the ASSB to operate at high temperatures, in addition, the complete filling of pores in the skeleton is a challenge, too little will lead to the limitation of the performance of composite solid electrolyte, and too much will affect the energy density of the battery.…”

Challenges and Solutions of Solid‐State Electrolyte Film for Large‐Scale Applications

“…The Li‐LiFePO 4 full cell shows stable cycling performance at 0.1 C (with a loading of 3 mg cm −2 ), and the specific capacity of the Li‐S full cell is still > 610 mAh g −1 at 60 °C after cycling for 300 cycles at 0.2 C. Similarly, Lu et al. [ 168 ] introduced graphene oxide into a polymer to create a flexible, self‐supporting, and ultrathin (80 um) SPE membrane. The novel three‐dimensional ionic transport paths in the SPE membrane, which are homogeneous and strongly interconnected, can facilitate ionic transport, and as a result, the RT ionic conductivity of SPE membrane is as high as 2.76 × 10 −3 S cm −1 , comparable to that of liquid electrolytes.…”

“…Although the solution casting method has been widely used for the large‐scale preparation of polymer‐based SSEs due to the simplicity and maturity of the process, the ability to incorporate a variety of additives as needed, the ease of preparing composite solid electrolytes with oxide/sulfide SSEs, and the ease of infiltration into porous and skeletal materials, the method has been prominent in CPEs in particular due to the integration of the advantages of each of the SPEs and inorganic SSEs. [ 170–172 ] There are five main structural designs studied, namely free‐standing SSE, [ 159–169 ] skeleton supporting SSE, [ 173–194 ] SSE with low tortuosity, [ 195–198 ] electrode‐supporting SSE [ 199–201 ] and in situ polymerization. [ 182,202–208 ] However, it is worth noting that the solution casting method is mainly based on SPE for the preparation and design of CSE, and the introduction of SPE will force the ASSB to operate at high temperatures, in addition, the complete filling of pores in the skeleton is a challenge, too little will lead to the limitation of the performance of composite solid electrolyte, and too much will affect the energy density of the battery.…”

Challenges and Solutions of Solid‐State Electrolyte Film for Large‐Scale Applications

Unveiling Confinement Engineering for Achieving High‐Performance Rechargeable Batteries

Nanocomposite design for solid-state lithium metal batteries: Progress, challenge, and prospects