聚焦离子束注入的锂源及其分析

Journal of Vacuum Science & Technology. B. Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena Pub Date : 2021-01-11 DOI:10.1116/6.0000645

Michael Titze, D. Perry, Elizabeth Auden, J. Pacheco, John B. S. Abraham, E. Bielejec

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引用次数: 3

摘要

我们提出了一种用于聚焦离子束应用的新型锂源。基于AuSi共晶合金，Li作为杂质加入，以减少暴露于空气时降解的影响。我们证明了光源在一个小时的过程中是稳定的，并且光斑尺寸可以达到小于10 nm。Li光束可以在半导体中达到数百纳米范围，并且沿路径长度产生的损伤最小。通过在硅基探测器上进行高分辨率离子束诱导电荷收集实验，对源性能进行了评价。对离子束源在离子束分析中的进一步应用进行了数值探讨;所研究的例子是基于通过卢瑟福后向散射实验探测半导体异质结构，其中Li束可以揭示用低能或高能He射体作为探针无法获得的信息。

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Lithium source for focused ion beam implantation and analysis

We present a new Li source for focused ion beam applications. Based on an AuSi eutectic alloy, Li is added as an impurity to minimize effects from degradation when exposed to air. We show the source is stable over the course of an hour and spot sizes ≲ 10 nm can be achieved. The Li beam can achieve hundreds of nanometer ranges in semiconductors with minimal damage being generated along the path length. The source performance is evaluated through a high-resolution ion beam induced charge collection experiment on an Si-based detector. Further application of the source for ion beam analysis is numerically explored; the example investigated is based on probing a semiconductor heterostructure through a Rutherford backscattering experiment, where the Li beam can reveal information that is inaccessible with either low energy or high energy He projectiles used as probes.

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Journal of Vacuum Science & Technology. B. Nanotechnology and Microelectronics: Materials, Processing, Measurement, and Phenomena

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