High accuracy and rapid dose measurements for ultra-low energy ion implantation using low energy x-ray emission spectroscopy

Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on Pub Date : 1900-01-01 DOI:10.1109/IIT.2002.1257964

S. Corcoran, C. Hombourger, P. Staub, M. Schuhmacher

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引用次数: 1

Abstract

This paper reports on the development and use of low energy x-ray emission spectroscopy (LEXES) for non-destructive dosimetry of low energy ion implants. Secondary Ion Mass Spectrometry (SIMS) is often considered the technique of choice for ion implant characterization. Unfortunately, SIMS measurements are time consuming and often require multiple measurements to build statistical confidence in the data. In addition, the complex surface ion yield transients-a fact of life in SIMS-can only be addressed by careful analytical protocols which add to the complexity of the analysis. Low energy high dose implants result in very high dopant concentrations (10%) in the first few nanometers that can compromise the quantitative accuracy of SIMS. LEXES is relatively immune to such matrix effects. For ion implant dosimetry, tool matching and wafer mapping, the LEXES technique will be shown to provide a greater than 10× improvement in throughput compared to SIMS for B, P, As and Ge. Repeatability for LEXES will be shown to be <1% for acquisition times of 1-8 minutes across a range of technologically relevant implant conditions.

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利用低能x射线发射光谱进行超低能离子注入的高精度、快速剂量测量

本文报道了低能x射线发射光谱(LEXES)在低能离子植入物无损剂量测定中的发展和应用。二次离子质谱法(SIMS)通常被认为是离子植入表征的首选技术。不幸的是，SIMS测量非常耗时，并且通常需要多次测量才能在数据中建立统计置信度。此外，复杂的表面离子产率瞬态- sims中的一个现实-只能通过仔细的分析协议来解决，这增加了分析的复杂性。低能量高剂量的植入会导致前几纳米的掺杂浓度非常高(10%)，这可能会损害SIMS的定量准确性。lex相对不受这种矩阵效应的影响。对于离子注入剂量测定、工具匹配和晶圆定位，lex技术将证明与SIMS相比，对B、P、As和Ge的通量提高了10倍以上。在一系列技术相关的植入条件下，lex的重复性将显示为<1%，采集时间为1-8分钟。

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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Ion Implantation Technology. 2002. Proceedings of the 14th International Conference on

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