High-safety cathode: through surface doping, bulk doping, and interface modification, the intrinsic Fermi level of the high specific energy battery materials is altered to inhibit oxygen participation in charge compensation, thereby constructing an effective protective barrier, preserving the stability of the cathode interface, and enhancing thermal safety.
High-safety anode: combined with high-safety coating technology and three-dimensional conductive-adhesive network, reducing the reactivity of the material with the electrolyte and improving chemical stability and thermal safety.
High-safety electrolyte: Various functional additives improve the interfacial Helmholtz layer, increases the battery's heat resistance temperature, reduces the battery's peak heat release temperature, and enhances battery safety.
Solid-state electrolyte: The in-situ polymerization technology of flame-retardant gel electrolyte replaces the volatile and flammable organic liquid electrolyte in traditional lithium batteries, improving the safety performance of the battery.