On the rseries extraction techniques for sub-22nm CMOS finfet and SiGe technologies

Proceedings of Technical Program of 2012 VLSI Technology, System and Application Pub Date : 2012-04-23 DOI:10.1109/VLSI-TSA.2012.6210128

L. Pantisano, G. Zschaetzsch, G. Hellings, R. Krom, S.H. Lee, R. Ritzenthaler, J. Mitard, G. Eneman, P. Roussel, T. Chiarella, L. Ragnarsson, M. Togo, W. Vandervorst, G. Groeseneken, A. Thean, N. Horiguchi

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引用次数: 1

Abstract

Introduction: Series resistance (Rseries) is a crucial factor for technology optimization and benchmarking [1-3]. Rseries is typically extracted in the bias conditions where Rseries dominates, i.e., linear regime and high Vgs by comparing multiple gate lengths. However this simple extraction is very challenging for sub22nm CMOS devices as changing a device length / width may change mobility or Rseries. For instance, this is the case for SiGe where the built-in stress effect [5,6] increases the channel mobility thus making the standard extraction difficult. The case is even more compelling for the bulk finfet case where the length width and height may not be known with the necessary precision and the gate stack itself may introduce (un)wanted stress components. As any Rseries extraction do rely critically on assumptions, in this paper we will first test the applicability and limits of several Rseries extraction techniques [1-3] and then use the best of both to gain new insights on the finfet and SiGe technology.

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亚22nm CMOS finet和SiGe技术的系列萃取技术

导论:串联电阻(Rseries)是技术优化和标杆的关键因素[1-3]。通过比较多个栅极长度，通常在Rseries占主导地位的偏置条件下提取Rseries，即线性状态和高Vgs。然而，这种简单的提取对于sub22nm CMOS器件来说是非常具有挑战性的，因为改变器件的长度/宽度可能会改变迁移率或r系列。例如，SiGe的情况就是这样，其中内置的应力效应[5,6]增加了通道的迁移性，从而使标准提取变得困难。这种情况对于批量finet的情况更有说服力，在这种情况下，长度、宽度和高度可能无法以必要的精度已知，并且栅极堆栈本身可能引入(不)需要的应力分量。由于任何r序列提取都严格依赖于假设，因此在本文中，我们将首先测试几种r序列提取技术的适用性和局限性[1-3]，然后使用两者的优点来获得关于finet和SiGe技术的新见解。

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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Proceedings of Technical Program of 2012 VLSI Technology, System and Application

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