Advanced Battery Materials and Technologies

Etched lithium anodes show more uniform plating and stripping
Chemical etching creates quasi-single-crystalline (110)-oriented lithium metal anodes that suppress dendrite growth and enable stable cycling for over 3,000 hours.
Clustered solvents and anions reduce lithium de-coordination energy
Study reveals how strong-coordination salts and solvents paradoxically improve low-temperature lithium-metal battery performance through cluster solvate formation and optimized charge distribution.
Low-temperature lithium-metal batteries improved by hierarchical solvation
Hierarchical solvating electrolyte enables high-performance lithium-metal batteries at extreme low temperatures through molecular engineering of solvation sheaths and solid electrolyte interphase.
In Situ Organoselenization for Ultrastable Li−Se Batteries
In situ organoselenization strategy converts selenium into organic selenide forms to prevent polyselenide shuttle in lithium-selenium batteries, achieving 92.87% capacity retention after 1300 cycles.
Frozen organic electrolyte conducts lithium ions
Demonstration that frozen ethylene carbonate with 0.2 m LiTFSI conducts Li+ via solid-state hopping (≈0.64 mS/cm, t+≈0.8), enabling liquid-level cell capacity and Li2O-rich SEI with extended.