Scaling challenges and device design requirements for high performance sub-50 nm gate length planar CMOS transistors

2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104) Pub Date : 2000-06-13 DOI:10.1109/VLSIT.2000.852814

T. Ghani, K. Mistry, P. Packan, Scott E. Thompson, M. Stettler, S. Tyagi, M. Bohr

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引用次数: 192

Abstract

Summary form only given. We investigate scaling challenges and outline device design requirements needed to support high performance-low power planar CMOS transistor structures with physical gate lengths (L/sub GATE/) below 50 nm. This work uses a combination of simulation results, experimental data and critical analysis of published data. A realistic assessment of gate oxide thickness scaling and maximum tolerable oxide leakage is provided. We conclude that the commonly accepted upper limit of 1 A/cm/sup 2/ for gate leakage is overly pessimistic and that leakage values of up to 100 A/cm/sup 2/ are deemed acceptable for future logic technology generations. Unique channel mobility and junction edge leakage degradation mechanisms, which become prominent at 50 nm L/sub GATE/ dimensions, are highlighted using quantitative analysis. Source-drain extension (SDE) profile design requirements to simultaneously minimize short channel effects (SCE) and achieve low parasitic resistance for sub-50 nm L/sub GATE/ transistors are described for the first time.

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高性能50nm栅极长度以下平面CMOS晶体管的缩放挑战和器件设计要求

只提供摘要形式。我们研究了缩放挑战，并概述了支持物理栅极长度(L/sub gate /)低于50 nm的高性能低功耗平面CMOS晶体管结构所需的器件设计要求。这项工作结合了模拟结果、实验数据和对已发表数据的批判性分析。提供了栅极氧化物厚度结垢和最大可容忍氧化物泄漏的现实评估。我们得出的结论是，通常接受的栅极泄漏上限为1 A/cm/sup 2/过于悲观，泄漏值高达100 A/cm/sup 2/被认为是未来逻辑技术世代可以接受的。独特的通道迁移率和结边泄漏退化机制，在50 nm L/sub GATE/尺寸下变得突出，使用定量分析强调。首次描述了源漏扩展(SDE)轮廓设计要求，以同时最小化短通道效应(SCE)并实现低于50 nm L/sub GATE/晶体管的低寄生电阻。

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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2000 Symposium on VLSI Technology. Digest of Technical Papers (Cat. No.00CH37104)

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