Preparation of porous silicon using magnesiothermic reduction of porous silica glass and electrode characteristics for lithium-ion batteries

IF 2.7 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY Journal of Materials Research Pub Date : 2024-04-26 DOI:10.1557/s43578-024-01344-2
Mina Deguchi, Kei Shinohara, Hironori Kobayashi, Kentaro Kuratani, Hikari Takahara, Haruhisa Shiomi, Arifumi Okada, Kohei Kadono
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Abstract

Magnesiothermic reduction was applied to porous silica glass grains with a characteristically interconnected pore structure. The prepared porous silicon maintained the morphology with pore size of approximately 30–40 nm, which was derived from the nanostructure of the starting silica glass. Medium-sized grains of the silica glass produced the largest silicon yield. This result could be explained based on the diffusion-controlled reaction mechanism, involving the reaction of SiO2 with Mg2Si to produce silicon. The electrochemical behavior was investigated using a coin-type cell composed of the prepared porous silicon–carbon mixtures and lithium foil electrodes. The initial charge and discharge capacities reached 1382 and 1187 mAh g−1, respectively, which were close to the theoretical value (1329 mAh g−1). After 50 charge/discharge cycles, 80% of the initial capacity is maintained. These results indicate that porous silicon derived from porous silica glass can be employed as an anode material for lithium-ion batteries.

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利用镁热还原多孔硅玻璃制备多孔硅及锂离子电池电极特性
镁热还原法适用于具有典型互连孔隙结构的多孔硅玻璃晶粒。制备的多孔硅保持了孔隙大小约为 30-40 纳米的形态,这种形态来自于起始硅玻璃的纳米结构。中等大小的硅玻璃颗粒产生的硅产量最大。这一结果可以用扩散控制反应机制来解释,即 SiO2 与 Mg2Si 反应生成硅。使用由制备的多孔硅碳混合物和锂箔电极组成的纽扣式电池对电化学行为进行了研究。初始充放电容量分别达到 1382 mAh g-1 和 1187 mAh g-1,接近理论值(1329 mAh g-1)。经过 50 次充放电循环后,初始容量保持在 80%。这些结果表明,从多孔硅玻璃中提取的多孔硅可用作锂离子电池的负极材料。
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来源期刊
Journal of Materials Research
Journal of Materials Research 工程技术-材料科学:综合
CiteScore
4.50
自引率
3.70%
发文量
362
审稿时长
2.8 months
期刊介绍: Journal of Materials Research (JMR) publishes the latest advances about the creation of new materials and materials with novel functionalities, fundamental understanding of processes that control the response of materials, and development of materials with significant performance improvements relative to state of the art materials. JMR welcomes papers that highlight novel processing techniques, the application and development of new analytical tools, and interpretation of fundamental materials science to achieve enhanced materials properties and uses. Materials research papers in the following topical areas are welcome. • Novel materials discovery • Electronic, photonic and magnetic materials • Energy Conversion and storage materials • New thermal and structural materials • Soft materials • Biomaterials and related topics • Nanoscale science and technology • Advances in materials characterization methods and techniques • Computational materials science, modeling and theory
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