Interlayer Engineering and Prelithiation: Empowering Si Anodes for Low‐Pressure‐Operating All‐Solid‐State Batteries

Silicon (Si) anodes, free from the dendritic growth concerns found in lithium (Li) metal anodes, offer a promising alternative for high‐energy all‐solid‐state batteries (ASSBs). However, most advancements in Si anodes have been achieved under impractical high operating pressures, which can mask detrimental electrochemo‐mechanical issues. Herein, we effectively address the challenges related to the low‐pressure operation of Si anodes in ASSBs by introducing an silver (Ag) interlayer between the solid electrolyte layer (Li6PS5Cl) and anode and prelithiating the anodes. The Si composite electrodes, consisting of Si/polyvinylidene fluoride/carbon nanotubes, are optimized for suitable mechanical properties and electrical connectivity. Although the impact of the Ag interlayer is insignificant at an exceedingly high operating pressure of 70 MPa, it substantially enhances the interfacial contacts under a practical low operating pressure of 15 MPa. Thus, Ag‐coated Si anodes outperform bare Si anodes (discharge capacity: 2430 vs 1560 mA h g−1). The robust interfacial contact is attributed to the deformable, adhesive properties and protective role of the in situ lithiated Ag interlayer, as evidenced by comprehensive ex situ analyses. Operando electrochemical pressiometry is used effectively to probe the strong interface for Ag‐coated Si anodes. Furthermore, prelithiation through the thermal evaporation deposition of Li metal significantly improves the cycling performance. Incorporating an Ag interlayer and prelithiation for CNT‐wired Si anodes in all‐solid‐state batteries overcomes low‐pressure operation challenges. The deformable and adhesive properties of the in situ lithiated Ag interlayer ensures robust interfacial contact, whereas prelithiation through thermal Li deposition compensates for Li loss during cycling, significantly enhancing electrochemical performance.