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Microemulsion-assisted synthesis of nanosized Li-Mn-O spinel cathodes for high-rate lithium-ion batteries

机译：微乳液辅助合成用于高倍率锂离子电池的纳米Li-Mn-O尖晶石阴极

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Li1.16Mn1.84O4 nanoparticles (50-90 nm) with cubic spinel structure are synthesized by combining a microemulsion process to produce ultrafine Mn(OH)2 nanocrystals (3-8 nm) with a solid-state lithiation step. The nanostructured lithium-rich Li1.16Mn1.84O4 shows stable cycling performance and superior rate capabilities as compared with the corresponding bulk material, for example, the nano-sized Li1.16Mn1.84O4 electrode shows stable reversible capacities of 74 mAhg-1 during the 1000th cycle at a high rate of 40 C between 3.0 and 4.5 V. In addition, Li1.16Mn1.84O4 nanoparticles also show high Li storage properties over an enlarged voltage window of 2.0-4.5 V with high capacities and stable cyclability, for example, delivering discharge capacities of 209 and 114 mAhg-1 at rates of 1 and 20 C, respectively.

机译：通过将微乳化工艺与固态锂化步骤相结合，以生产超细Mn（OH）2纳米晶体（3-8 nm），合成了具有立方尖晶石结构的Li1.16Mn1.84O4纳米颗粒（50-90 nm）。与相应的块状材料相比，纳米结构的富锂Li1.16Mn1.84O4表现出稳定的循环性能和优异的倍率性能，例如，纳米Li1.16Mn1.84O4电极在放电过程中显示出74 mAhg-1的稳定可逆容量。在3.0至4.5 V之间以40 C的高速率进行第1000次循环。此外，Li1.16Mn1.84O4纳米粒子还显示出在2.0-4.5 V的更大电压窗口内具有高容量和稳定循环性的高Li储存性能。分别以1和20 C的速率提供209和114 mAhg-1的放电容量。

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Rui, Xianhong; Sun, Wenping; Yan, QingYu; Lim, Tuti M; Skyllas-Kazacos, Maria;
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1. Microemulsion-Assisted Synthesis of Nanosized Li-Mn-O Spinel Cathodes for High-Rate Lithium-Ion Batteries [J] . Rui Xianhong, Sun Wenping, Yan Qingyu, ChemPlusChem . 2014,第12期

机译：用于高速锂离子电池的微乳液辅助合成纳米型Li-Mn-O尖晶石阴极
2. Facile synthesis of Li-rich layered oxides with spinel-structure decoration as high-rate cathode for lithium-ion batteries [J] . Han Jiangtao, Zheng Hongfei, Hu Zhenyu, Electrochimica Acta . 2019,第期

机译：用尖晶石结构装饰作为锂离子电池的高速阴极的锂分层氧化物的构成
3. Surface-segregated, high-voltage spinel lithium-ion battery cathode material LiNi0.5Mn1.5O4 cathodes by aluminium doping with improved high-rate cyclability [J] . Luo Ying, Lu Taolin, Zhang Yixiao, Journal of Alloys and Compounds: An Interdisciplinary Journal of Materials Science and Solid-state Chemistry and Physics . 2017,第期

机译：表面隔离，高压尖晶石锂离子电池正极材料LiNi0.5Mn1.5O4阴极通过铝掺杂，具有改善的高速阻止性
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机译：SpinEL Li-Mn-O毫米波场中的固体化学合成作为Li离子电池的阴极材料
5. High power 4.7 V nanostructured spinel lithium manganese nickel oxide lithium-ion battery cathode materials. [D] . Kunduraci, Muharrem. 2007

机译：大功率4.7 V纳米结构尖晶石锂锰酸锂镍离子电池正极材料。
6. Facile One-Step Dynamic Hydrothermal Synthesis of Spinel LiMn2O4/Carbon Nanotubes Composite as Cathode Material for Lithium-Ion Batteries [O] . Chaoqi Shen, Hui Xu, Liu Liu, 2019

机译：锂离子电池正极材料尖晶石LiMn2O4 /碳纳米管的快速一步动态水热合成
7. Thermodynamic Investigation and Cathode Performance of Li-Mn-O Spinel System as Cathode Active Material for Lithium Secondary Battery. [O] . Yasushi IDEMOTO, Tomohiro OZASA, Nobuyuki KOURA 2001

机译：Li-Mn-O尖晶石系统的热力学研究和阴极性能作为锂二电池的阴极活性材料。
8. Synthesis of Nanosized Lithium Manganate For Lithium-ion Secondary Batteries. [R] . Wang, H., Lin, Y., Wen, M., 2002

机译：锂离子二次电池用纳米锂锰酸锂的合成。

Microemulsion-assisted synthesis of nanosized Li-Mn-O spinel cathodes for high-rate lithium-ion batteries

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