NMOS源漏扩展离子注入加热衬底

2014 20th International Conference on Ion Implantation Technology (IIT) Pub Date : 2014-10-30 DOI:10.1109/IIT.2014.6939768

L. Pipes, L. McGill, A. Jahagirdar

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引用次数: 10

摘要

现代CMOS制造中三维结构(三栅极、FinFET等)的出现要求采用新技术来减轻离子植入的损伤效应。传统的束线离子植入提供了一种很好理解和很好控制的鳍掺杂方法，因为源/漏鳍和/或多晶硅栅极之间的间距允许它不遮挡有源器件结构。然而，传统的束线离子植入也会导致硅损伤，这在与现代三维晶体管相关的尺寸上尤其成问题。在这项工作中，我们将传统的光束线离子植入到加热到高温的硅晶圆衬底中，以减轻离子植入的损伤效应。使用该技术减少损伤的净影响显示在平面晶片，地形晶片，最后是22纳米NMOS三极管器件上。

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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NMOS source-drain extension ion implantation into heated substrates

The emergence of three-dimensional structures (Tri-gate, FinFET, etc.) in modern CMOS manufacturing have required new technologies to mitigate ion implant damage effects. Traditional beamline ion implant provides a well understood and well controlled approach to fin doping given that the pitches between source/drain fins and/or the polysilicon gates allow it without shadowing of active device structures. However, traditional beamline ion implant also causes silicon damage that can prove particularly problematic at the dimensions associated with modern 3-dimensional transistors. In this work we perform traditional beamline ion implants into silicon wafer substrates that are heated to elevated temperatures in an effort to mitigate ion implant damage effects. The net impact of damage mitigation using this technology is shown on flat wafers, topographical wafers, and finally on 22 nm NMOS trigate devices.

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2014 20th International Conference on Ion Implantation Technology (IIT)

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