锂离子电池负极材料大孔硅的制备

RAN Pub Date : 2016-04-01 DOI:10.11159/ICNNFC16.112
M. Kim, Yeon Baek Seong, Tae Hoon Lee, Changhyun Park, Jin Wook Lee, W. Choi, N. Park, T. Lee
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引用次数: 0

摘要

在锂离子电池中,锂离子在充电和放电过程中在电池的阳极和阴极之间移动。碳基材料,如石墨和碳微珠已被用作锂离子电池的负极材料。但碳基负极材料具有库仑效率低、不可逆容量大的特点。因此,合金阳极材料中掺入其他材料,如Sn、Sb、Ge和Si等,以增强阳极材料的容量[2]。将硅作为锂离子电池的负极材料,提高了负极材料的容量。硅具有最高的比容量(4212 mAh/g,形成合金/脱合金材料)、高能量密度和良好的安全性[3]。尽管硅具有较高的比容量,但在插拔锂过程中往往会出现膨胀现象。在本研究中,为了防止膨胀现象,硅中存在宏观孔隙。以四甲基邻位硅酸盐(TMOS)和聚甲基丙烯酸甲酯(PMMA)为原料合成了大孔硅。采用悬浮聚合法制备了纳米级PMMA微珠作为大孔模板。PMMA珠的尺寸为300nm,在水中呈扩散状态。TMOS被用作合成大孔二氧化硅的前驱体[1]。将TMOS和PMMA的混合物在650℃空气净化下热处理5 h。然后将大孔二氧化硅与铝粉混合。用铝粉将大孔二氧化硅转化为硅。将大孔硅铝混合料浆在650℃氩气吹扫下热处理5 h。使用还原剂可将大孔硅还原为大孔硅。同时,将铝粉作为还原剂氧化还原二氧化硅。金属氧化物,如阳极材料中的Al2O3,可以抑制硅。因此,用HCl和H3PO4处理还原后的大孔硅样品,以去除Al2O3。SEM分析证实了硅的宏观孔隙。通过XRD和XPS分析证实了二氧化硅的还原作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Preparation of Macro-porous Si as a Anode Material for Li-ion Battery
Extended Abstract In lithium-ion batteries, lithium ions move between the battery's anode and cathode during charge and discharge. Carbon-based materials, like graphite and carbon micro-bead have used as anode materials for Li-ion battery. However, carbon-based anode materials have low coulombic efficiency and high irreversible capacity. In this reason, the alloys anode material mixed with the other material, such as Sn, Sb, Ge and Si etc., for enhancing the capacity of anode materials [2]. The silicon is used as a anode material for Li-ion battery to boosting the capacity of anode materials. The Silicon has the highest specific capacity (4212 mAh/g with formation of Alloy/de-alloy materials), high energy density and good safety [3]. Even though the silicon has high specific capacity, it often exhibits a swelling phenomenon during Li insertion and extraction. In this study, macro pores are existed in the silicon for prevention of the swelling phenomenon. The macroporous silicon was synthesized from TMOS(Tetra methyl ortho silicate) and PMMA(Poly methyl methacrylate). The nanosized PMMA beads used as a template for the formation of macro-pores was synthesized by the suspension polymerization method. The PMMA beads had 300nm size and it used a diffusing state in water. The TMOS was used as the precursor for the synthesis of macro-porous silica [1]. A mixture of TMOS and PMMA was thermal treated at 650 °C for 5 h under the air purging. Then, the macro-porous silica was mixed with aluminum powders. The aluminum powder was used for the conversion of macro-porous silica to silicon. The macro-porous silica and aluminum mixture slurry was thermal treated at 650 °C for 5 h under the argon purging. The macro-porous silica can be reduced to the macro-porous silicon with the reducing agents. Meanwhile, aluminum powder, used as reducing agent, is oxided for the reduction of silica. A metal oxide, like a Al2O3 in anode materials, can repress silicon. Therefore, the reduced macro-porous silicon sample was treated with HCl and H3PO4 in order to remove Al2O3. The macro pores of silicon were confirmed by SEM analysis. The reducing of silica was confirmed by XRD and XPS analysis.
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