采用 MXene 和非晶碳双重封装的 LiMn0.6Fe0.4PO4 结构可实现高性能和超稳定锂电池

IF 12.7 1区化学 Q1 CHEMISTRY, MULTIDISCIPLINARY

ACS Central Science Pub Date : 2024-11-05 DOI:10.1039/d4ta06323f

Yang Song, Haidong Zhong, Tingting Hu, Qizhi Chen, Lei Shi, Jun Du, Changyuan Tao, Qian Zhang

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引用次数: 0

摘要

LiMnxFe1-xPO4 （LMFP）材料具有高能量密度和优异的循环稳定性，是电动汽车和其他高能量密度应用领域前景广阔的正极材料。然而，锂离子扩散系数低和电子导电性差限制了 LMFP 的进一步发展。在本研究中，我们设计了一种涉及静电自组装和原位石墨化的策略，以制备具有 LMFP（LiMn0.6Fe0.4PO4）双重封装的致密 LMFP@MXene@C 结构。由于石墨化程度高、比表面积大、锂离子定向传输性能优异以及致密的双包覆结构，制备的 LMFP@MXene@C 阴极具有可观的可逆容量（1 C 条件下循环 100 次后容量为 153.58 mAh/g），并且具有出色的速率性能和稳定性（5 C 条件下循环 1200 次后容量保持率为 91.26%）。根据详细的 TEM、原位 XRD 技术以及系统动力学和结构稳定性评估分析，其优异的电化学稳定性和 Li+ 传输性能可归功于二维 MXene 层状通道和无定形 C 层形成的网络结构。这种结构促进了电子和离子的快速转移，有效地提供了体积缓冲和结构保护。这种双重封装策略为制备特殊的电化学阴极材料提供了一种可行的方法。

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Dually Encapsulated LiMn0.6Fe0.4PO4 Architecture with MXene and Amorphous Carbon to Achieve High-performance and Ultra-stable Lithium Battery

LiMnxFe1-xPO4 (LMFP) materials, with their high energy density and excellent cycle stability, are promising cathode materials for electric vehicles and other high-energy-density applications. However, the low lithium-ion diffusion coefficient and poor electronic conductivity limit the further development of LMFP. In this study, we designed a strategy involving electrostatic self-assembly and in-situ graphitization to fabricate a dense LMFP@MXene@C structure with dual encapsulation of LMFP (LiMn0.6Fe0.4PO4). Owing to its high degree of graphitization, large surface area, excellent Li-ion directional transport, and dense dual encapsulation structure, the fabricated LMFP@MXene@C cathode exhibits a considerable reversible capacity (153.58 mAh/g after 100 cycles at 1 C) with outstanding rate performance and stability (maintaining 91.26% of its capacity after 1200 cycles at 5 C). According to the detailed TEM, in-situ XRD techniques, and system dynamics and structural stability assessments analysis, the superior electrochemical stability and Li+ transport can be attributed to the network structure formed by 2D MXene layered channels and amorphous C layers. This structure facilitates the rapid electron and ion transfer, effectively providing volumetric buffering and structural protection. The dually encapsulated strategy offers a feasible approach for the preparation of exceptional electrochemical cathode materials.

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来源期刊

ACS Central Science Chemical Engineering-General Chemical Engineering

CiteScore

25.50

自引率

0.50%

发文量

194

审稿时长

10 weeks

期刊介绍： ACS Central Science publishes significant primary reports on research in chemistry and allied fields where chemical approaches are pivotal. As the first fully open-access journal by the American Chemical Society, it covers compelling and important contributions to the broad chemistry and scientific community. "Central science," a term popularized nearly 40 years ago, emphasizes chemistry's central role in connecting physical and life sciences, and fundamental sciences with applied disciplines like medicine and engineering. The journal focuses on exceptional quality articles, addressing advances in fundamental chemistry and interdisciplinary research.