발간논문

Home > KJMM 논문 > 발간논문

Vol.60, No.11, 851 ~ 858, 2022
Title
Fabricating and Probing Forsterite Li-ion Battery Anode Electrodes
김동주 Dong-ju Kim , 박병남 Byoung-nam Park
Abstract
In an effort to minimize irreversible capacity loss and volume expansion, research on Si nanocomposite materials with a SiOx/Mg2SiO4/SiOx structure through a magnesiothermic reduction process (MTR) has attracted much attention from researchers. Mg2SiO4(forsterite) has been shown to improve the initial coulombic efficiency (ICE) by minimizing the irreversible capacity loss due to pulverization and highvolume expansion of the Si-based anode complexes. In this study, forsterite was synthesized as the main phase by Mg vapor control in the MTR process. We used an electrophoretic deposition system to investigate the intrinsic electrochemical properties of forsterite, which served as a buffer for the improvement of ICE, associated with the lithiation/delithiation process. Importantly, a stable specific capacity of up to 200 mAh/ g was achieved during the charging/discharging process, demonstrating its potential use as an anode electrode. We also found that no significant capacity was found by alloying with Si. In other words, there is a lithium storage mechanism unique to forsterite which is not related to the Si alloying reaction in the storage mechanism. The results presented here are the first demonstration of a forsterite lithium-ion battery; forsterite has only been considered as a buffer layer of the Si/SiO composite structure. Furthermore, the finding is of crucial importance as it provides the basis for various approaches to develop reversible and high power li-ion battery anodes by synthesizing the Si composite through MTR. (Received 5 March, 2022; Accepted 1 September, 2022)
Key Words
forsterite, magnesiothermic reaction, li-ion battery, silicon composite
| PDF
대한금속∙재료학회 (06633) 서울시 서초구 서초대로 56길 38 대한금속∙재료학회 회관 (서초1동 1666-12번지)
Tel : 070-4266-1646 FAX : 02-557-1080 E-mail : metal@kim.or.kr
Copyright ⓒ 2013 사단법인 대한금속∙재료학회 All rights reserved.