Improved electrochemical properties in the Li3Fe2(PO4)3 by titanium and vanadium doping

“…29 Researchers have conducted a lot of research on improving the mobility of lithium-ion and electrons in cathode materials of LIBs. The study finds that the main strategies to address these two problems include the synthesis of nanostructures, [30][31][32][33] the coating of conductive carbon, [34][35][36] modification of surface coatings, 37,38 doping of other ions, [39][40][41][42] synergistic effects of the above mechanisms [43][44][45] and other new methods. 46,47 Here, we introduce the three major effects that limit the development for fast charging technology of LIBs and their degradation mechanisms.…”

Review—Key Strategies to Increase the Rate Capacity of Cathode Materials for High Power Lithium-Ion Batteries

“…29 Researchers have conducted a lot of research on improving the mobility of lithium-ion and electrons in cathode materials of LIBs. The study finds that the main strategies to address these two problems include the synthesis of nanostructures, [30][31][32][33] the coating of conductive carbon, [34][35][36] modification of surface coatings, 37,38 doping of other ions, [39][40][41][42] synergistic effects of the above mechanisms [43][44][45] and other new methods. 46,47 Here, we introduce the three major effects that limit the development for fast charging technology of LIBs and their degradation mechanisms.…”

Review—Key Strategies to Increase the Rate Capacity of Cathode Materials for High Power Lithium-Ion Batteries

Titanium-Doped Nickel-Rich Layered LiNi0.8Co0.2O2 as High-Performance Cathode Material for Lithium-Ion Batteries

Methods for enhancing the capacity of electrode materials in low-temperature lithium-ion batteries