制备具有定制电化学特性的氧化硅-碳复合材料,用于锂离子电池负极

C Pub Date : 2023-12-01 DOI:10.3390/c9040114
Sang Jin Kim, Seung-Jae Ha, Jea Uk Lee, Young-Pyo Jeon, Jin-Yong Hong
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摘要

为了实现高效、高稳定性的锂离子电池,开发了一种氧化硅基碳复合材料作为负极材料。为了最大限度地减少充放电时体积收缩/膨胀引起的结构缺陷(开裂和粉碎),采用氧化硅(SiOx)。采用机械熔合法将沥青(一种碳前驱体)引入SiOx表面。引入的沥青前驱体可以通过稳定和碳化过程容易地转化为碳层,从而产生SiOx@C。该碳层在缓冲SiOx在锂化/脱锂过程中的体积膨胀、提高电导率和防止与电解质直接接触方面起着至关重要的作用。为了提高SiOx的容量和循环稳定性,根据SiOx与沥青的混合比例以及负极材料中的负载量,对SiOx@C复合材料的电化学性能进行了比较分析。与原始SiOx相比,通过优化实验条件制备的SiOx@C复合材料的放电容量和初始库仑效率分别提高了约1.6倍和1.8倍。此外,即使经过300多次充放电测试,它也表现出出色的容量保持和循环稳定性。
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Preparation of Silicon Oxide-Carbon Composite with Tailored Electrochemical Properties for Anode in Lithium-Ion Batteries
For high-efficiency and high-stability lithium ion batteries, a silicon oxide-based carbon composite has been developed as an anode material. To minimize structural defects (cracking and pulverization) due to volumetric contraction/expansion during charge/discharge, silicon oxide (SiOx) is adopted. A pitch—a carbon precursor—is introduced to the surface of SiOx using the mechanofusion method. The introduced pitch precursor can be readily transformed into a carbon layer through stabilization and carbonization processes, resulting in SiOx@C. This carbon layer plays a crucial role in buffering the volume expansion of SiOx during lithiation/delithiation processes, enhancing electrical conductivity, and preventing direct contact with the electrolyte. In order to improve the capacity and cycle stability of SiOx, the electrochemical performances of SiOx@C composites are comparatively analyzed according to the mixing ratio of SiOx and pitch, as well as the loading amount in the anode material. Compared to pristine SiOx, the SiOx@C composite prepared through the optimization of the experimental conditions exhibits approximately 1.6 and 1.8 times higher discharge capacity and initial coulombic efficiency, respectively. In addition, it shows excellent capacity retention and cycle stability, even after more than 300 charge and discharge tests.
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