High-Voltage “Single-Crystal” Cathode Materials for Lithium-Ion Batteries

Abstract: To boost the use of electronic devices and driving mileage of electric vehicles, it is urgent to develop lithium-ion batteries (LIBs) with higher energy density and longer life. High-voltage and high-capacity cathode materials, such as LiCoO 2 , LiNi 0.5 Mn 1.5 O 4 , Ni-rich layered oxides, and lithium-rich layered oxides, are critically important for LIBs to obtain high energy density. Among various forms of these materials, "single-crystal" cathodes (SCCs) have shown many advantages over other forms for indu… Show more

“…This result suggests that the SCC behavior usually observed in polycrystalline NMC cathodes 39 is also present in the deep-cycled LCO cathode with a single-crystalline microstructure, which is usually considered not to crack easily. 49 Similar cracking behavior was previously reported in deep-cycled single-crystalline NMC 50 and LCO 7,24 cathodes. Considering the high catalytic capability of the LCO surface that may promote more intensive side reactions, a ''good'' electrolyte or proper surface modification that can passivate the surface cracks and thus suppress the SCC, is required for 44.5 V Li LCO.…”

Stabilizing electrode–electrolyte interfaces to realize high-voltage Li||LiCoO₂ batteries by a sulfonamide-based electrolyte

“…This result suggests that the SCC behavior usually observed in polycrystalline NMC cathodes 39 is also present in the deep-cycled LCO cathode with a single-crystalline microstructure, which is usually considered not to crack easily. 49 Similar cracking behavior was previously reported in deep-cycled single-crystalline NMC 50 and LCO 7,24 cathodes. Considering the high catalytic capability of the LCO surface that may promote more intensive side reactions, a ''good'' electrolyte or proper surface modification that can passivate the surface cracks and thus suppress the SCC, is required for 44.5 V Li LCO.…”

Stabilizing electrode–electrolyte interfaces to realize high-voltage Li||LiCoO₂ batteries by a sulfonamide-based electrolyte

“…Intriguingly, SC sample showed the superior rate performance at both low and high current density, which is totally different from rate results in previous studies. [ 15a ] Therefore, the galvanostatic intermittent titration technique tests were performed to calculate Li + diffusion coefficient ( D Li + ) and study the kinetics behaviors of both PC‐LLNMO and SC‐LLNMO electrodes (Figure S4, Supporting Information), [ 15b,c ] in which SC sample harvested the higher D Li + values in both TM‐based and oxygen‐related regions. It proved the superior rate performances can be obtained within SC sample during both charging and discharging processes compared with PC sample.…”

Restraining Oxygen Release and Suppressing Structure Distortion in Single‐Crystal Li‐Rich Layered Cathode Materials

“…A direct strategy to reduce grain boundary stress is to fabricate single‐crystal cathode particles. [ 118,119 ] Advanced mechanical strength and more homogeneous electrochemical reactions can be achieved due to the high crystallinity and isotropy orientation of single‐crystal cathode materials.…”

A Review of Degradation Mechanisms and Recent Achievements for Ni‐Rich Cathode‐Based Li‐Ion Batteries