Potential use of laser-induced breakdown spectroscopy combined laser cleaning for inspection of particle defect components on silicon wafer

IF 1.5 2区 物理与天体物理 Q3 ENGINEERING, ELECTRICAL & ELECTRONIC
Lituo Liu, Guannan Li, Weihu Zhou, Xiaobin Wu, Yu Wang
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引用次数: 0

Abstract

Abstract. The contamination control of silicon wafer surface is more and more strict. Many investigations have been done to inspect defects on silicon wafer. However, rare studies have been reported on defect component inspection, which is also critical to trace the source of defects and monitor manufacturing processes in time. In order to inspect the components of contaminated particles on silicon wafer, especially with a high-speed, in-line mode and negligible damage, a dual nanosecond pulse laser system with both wavelengths at 532 nm is designed, in which one laser pumps the particles away from the wafer surface with negligible damage, the other laser breaks down the particles in the air above the wafer surface to obtain the emission lines of the contaminated particles by a spectroscopy with intensified charge coupled device. The sensitivity of the dual pulse laser system is evaluated. The particle dynamic process after pump is analyzed. The results in this work provide a potential on-line method for the semiconductor industry to trace the sources of defects during the manufacture process.
激光诱导击穿光谱联合激光清洗在硅片颗粒缺陷成分检测中的潜在应用
摘要硅片表面的污染控制越来越严格。人们对硅片缺陷的检测进行了许多研究。然而,对于缺陷部件的检测却鲜有报道,而缺陷部件的检测对于及时追踪缺陷来源和监控制造过程至关重要。为了检测硅片上污染颗粒的组成,特别是在高速、在线模式和可忽略损伤的情况下,设计了一种双纳秒脉冲激光系统,该系统的两个波长都在532 nm,其中一个激光将颗粒从硅片表面泵出,而损伤可忽略不计。另一种激光器通过带强化电荷耦合器件的光谱学对晶圆表面上方空气中的粒子进行分解,得到污染粒子的发射谱线。对双脉冲激光系统的灵敏度进行了评价。分析了泵送后颗粒的动态过程。这项工作的结果为半导体工业在制造过程中追踪缺陷来源提供了一种潜在的在线方法。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
CiteScore
3.40
自引率
30.40%
发文量
0
审稿时长
6-12 weeks
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