| Literature DB >> 27775893 |
Won Chul Cho1,2, Hye Jin Kim3, Hae In Lee1, Myung Won Seo1,2, Ho Won Ra1, Sang Jun Yoon1,2, Tae Young Mun1, Yong Ku Kim1, Jae Ho Kim1,2, Bo Hwa Kim1, Jin Woo Kook1, Chung-Yul Yoo1, Jae Goo Lee1,2, Jang Wook Choi3.
Abstract
Nanostructured silicon (Si) is useful in many applications and has typically been synthesized by bottom-up colloid-based solution processes or top-down gas phase reactions at high temperatures. These methods, however, suffer from toxic precursors, low yields, and impractical processing conditions (i.e., high pressure). The magnesiothermic reduction of silicon oxide (SiO2) has also been introduced as an alternative method. Here, we demonstrate the reduction of SiO2 by a simple milling process using a lab-scale planetary-ball mill and industry-scale attrition-mill. Moreover, an ignition point where the reduction begins was consistently observed for the milling processes, which could be used to accurately monitor and control the reaction. The complete conversion of rice husk SiO2 to high purity Si was demonstrated, taking advantage of the rice husk's uniform nanoporosity and global availability, using a 5L-scale attrition-mill. The resulting porous Si showed excellent performance as a Li-ion battery anode, retaining 82.8% of the initial capacity of 1466 mAh g-1 after 200 cycles.Entities:
Keywords: attrition mill; ignition time; lithium-ion battery; magnesio-milling reduction; silicon anode
Year: 2016 PMID: 27775893 DOI: 10.1021/acs.nanolett.6b03762
Source DB: PubMed Journal: Nano Lett ISSN: 1530-6984 Impact factor: 11.189