利用真空硅热还原法制备一氧化硅纳米线及其工艺优化

IF 2.1 4区 材料科学 Q3 MATERIALS SCIENCE, MULTIDISCIPLINARY JOM Pub Date : 2024-08-06 DOI:10.1007/s11837-024-06702-3
Zixiang Zhou, Qingchun Yu, Shubiao Yin, Yong Deng
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引用次数: 0

摘要

一氧化硅纳米线因其卓越的光电特性而在二十一世纪的科技中无处不在,广泛应用于半导体制造和新兴能源领域。虽然大量研究都集中在定制材料特性方面,但很少有人关注合成过程中工艺参数对一氧化硅生产率的影响。通过响应面方法,研究了保温时间、加热温度和 Si/SiO2 摩尔比对一氧化硅挥发率的影响。通过真空硅热还原法制备一氧化硅纳米线的优化旨在实现最高效率。根据建立的数学模型,当保温时间为 126 分钟、加热温度为 1663 K、摩尔比为 1 时,一氧化硅的挥发率达到 92.057%。此外,还对系统的还原渣进行了表征和分析。结果表明,真空条件可以降低硅热还原的起始温度,从而促进氧化硅(g)的挥发。
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Preparation and Process Optimization of Silicon Monoxide Nanowires by Vacuum Silicothermic Reduction

Silicon monoxide nanowires have become ubiquitous in twenty-first century technology due to their superior photoelectric properties, widely utilized in semiconductor manufacturing and emerging energy fields. While numerous studies have concentrated on tailoring material properties, scant attention has been paid to the impact of process parameters on the productivity of silicon monoxide during synthesis. Through response surface methodology, the effects of holding time, heating temperature, and Si/SiO2 molar ratio on the volatilization ratio of silicon monoxide have been investigated. The optimization of silicon monoxide nanowire preparation via vacuum silicothermic reduction was aimed at achieving maximum efficiency. According to the established mathematical model, the volatilization ratio of silicon monoxide reaches 92.057% when the holding time is 126 min, the heating temperature is 1663 K, and the molar ratio is 1. A comprehensive analysis revealed that temperature is the most significant factor affecting silicon monoxide volatilization among the studied parameters. Furthermore, the reduction slag of the system was characterized and analyzed. The results indicate that vacuum conditions can lower the starting temperature of the silicothermic reduction, thereby promoting the volatilization of SiO(g).

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来源期刊
JOM
JOM 工程技术-材料科学:综合
CiteScore
4.50
自引率
3.80%
发文量
540
审稿时长
2.8 months
期刊介绍: JOM is a technical journal devoted to exploring the many aspects of materials science and engineering. JOM reports scholarly work that explores the state-of-the-art processing, fabrication, design, and application of metals, ceramics, plastics, composites, and other materials. In pursuing this goal, JOM strives to balance the interests of the laboratory and the marketplace by reporting academic, industrial, and government-sponsored work from around the world.
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