Synthesizing high performance LNMO cathode materials with porous structure by manipulating Reynolds number in a microreactor.
Tongli LiuHongjie DengFa HeYuqing WuZhenguo WuFang WanTing ChenWenhua XuYang SongXiao-Dong GuoPublished in: Nanotechnology (2024)
The demand for Lithium-ion batteries (LIBs) has significantly grown in the last decade due to their extensive use electric vehicles (EVs). To further advance the commercialization of LIBs for various applications, there is a pressing need to develop electrode materials with enhanced performance. The porous microsphere morphology LiNixMn2-xO4 (LNMO) is considered to be an effective material with both high energy density and excellent rate performance. Nevertheless, LNMO synthesis technology still has problem such as long reaction time, high energy consumption and environmental pollution. Herein, LNMO microsphere was successfully synthesized with short precursors reaction time (18 seconds) at 40oC without using chelating agent by microreaction technology combined solid-state lithiation. The optimized LNMO cathode shows microsphere (~8μm) morphology stacked by nano primary particles, with abundant mesoporous and fully exposed low-energy plane. The electrochemical analysis indicates that the optimized LNMO cathode demonstrates 97.33% capacity retention even after 200 cycles at 1C. Additionally, the material shows a highly satisfactory discharge capacity of 92.3 mAh·g-1 at 10C. Overall, microreaction technology is anticipated to offer a novel approach in the synthesis of LNMO cathode materials with excellent performance.