Synthesis of silicon nanoparticles with various additions of inert salt as scavenger agent during reduction by the magnesiothermic method as anode lithium-ion batteries

Q1 Materials Science Materials Science for Energy Technologies Pub Date : 2023-09-27 DOI:10.1016/j.mset.2023.09.003

Andriayani , Saur Lumban Raja , Amir Hamzah Siregar , Amru Daulay , Susilo Sudarman

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Abstract

A heat scavenger agent magnesiothermic reduction of quartz sand was used to make Si nanoparticles in a way that can be easily scaled up. Its source of SiO₂ is safe for the environment, easy to get, and cheap. It can make silicon nanoparticles that work well as an anode material for Li-ion batteries. It is known that using inert salt NaCl has a better characterization of Si and electrochemical performance than KCl, KBr, and CaCl₂. XRD diffractogram show 2θ are formed at 27.42°, 47.30°, 56.11°, 69.19°, and 76.37°. The surface area shows 9.75 m²/g, and the pore size is 15.35 Å. In the TEM images, it is found that the silicon shape is spherical. The electrical conductivity voltage of 1 V is 2599.33 µS/cm. The cyclic voltammetry curve during the highest oxidation is 0.57 V, and the lowest oxidation peak is 0.16 V. After the first cycle, the Rs is 4.22 Ω, and the Rct formed is 51.19 Ω. The first discharge capacity is 2599.57 mAh/g, corresponding to coulombic efficiencies at 97.12 %.

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镁热法还原过程中添加不同惰性盐作为清除剂合成纳米硅作为负极锂离子电池

使用石英砂的热清除剂镁热还原法以一种易于放大的方式制备硅纳米颗粒。它的SiO2来源对环境安全，易于获得，而且价格低廉。它可以制造出作为锂离子电池阳极材料的硅纳米颗粒。已知使用惰性盐NaCl比KCl、KBr和CaCl2具有更好的Si表征和电化学性能。XRD衍射图显示，在27.42°、47.30°、56.11°、69.19°和76.37°处形成2θ。表面积为9.75m2/g，孔径为15.35Å。在TEM图像中，发现硅的形状为球形。1 V的导电电压为2599.33µS/cm。最高氧化过程中的循环伏安曲线为0.57V，最低氧化峰为0.16V。第一次循环后，Rs为4.22Ω，形成的Rct为51.19Ω。第一次放电容量为2599.57mAh/g，库仑效率为97.12%。

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