Enabling 4.6 V LiNi0.6Co0.2Mn0.2O2 cathodes with excellent structural stability: combining surface LiLaO2 self-assembly and subsurface La-pillar engineering

The solution proposed in this article is expected to provide direction for managing the internal structure and interface stability of NCM and can be extended to other cathode applications.

Insights into the electrochemical performance of metal fluoride cathodes for lithium batteries

Electrochemical characterization of cylindrical full batteries. (A

Insights into the electrochemical performance of metal fluoride cathodes for lithium batteries

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Atomic‐resolution STEM images of a) P‐LNCM pristine, b) P‐LNCM

Guolin Cao's research works Central South University, Changsha

Electrochemical performance of the MXene‐Si@C anode with postmortem SEM

Insights into the electrochemical performance of metal fluoride cathodes for lithium batteries

Conductivity measurements and structural characterization of

In situ XRD patterns of a‐1) U‐LNCM, a‐2) P‐LNCM, and a‐3) B‐LNCM

Lithium metal stabilization for next-generation lithium-based batteries: from fundamental chemistry to advanced characterization and

PDF) Enabling 4.6 V LiNi0.6Co0.2Mn0.2O2 cathodes with excellent structural stability: combining surface LiLaO2 self-assembly and subsurface La-pillar engineering

Correlating structural changes of the improved cyclability upon Nd-substitution in LiNi0.5Co0.2Mn0.3O2 cathode materials - ScienceDirect

Xia LU, Professor, PhD

Recent progress of multilayer polymer electrolytes for lithium batteries