Epitaxialy defined (ED) FinFET: to reduce VT variability and enable multiple VT

70th Device Research Conference Pub Date : 2012-06-18 DOI:10.1109/DRC.2012.6256997

S. Mittal, S. Gupta, A. Nainani, M. Abraham, K. Schuegraf, S. Lodha, U. Ganguly

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引用次数: 5

Abstract

Device variability has become a major concern for CMOS technology [1]. Various sources of variability include Random Dopant Fluctuation (RDF), Gate Edge Roughness (GER) and Line Edge Roughness (LER) [2]. The introduction of FinFETs at 22nm node has two issues. Firstly, the effect of RDF is considerably reduced due to undoped fins [3]. But the aggressive fin width (Wfin) requirement (~Lg/3 [4]) to reduce short channel effect aggravates the electrical impact of LER and makes it greatest contributor to patterning induced variability [2]. Moreover, the edge roughness does not scale with technology and remains independent of the type of lithography used [5]. Secondly, multiple threshold voltage (VT) is achieved in planar technology by various patterned implant steps, which is unavailable for FinFET technology as the fin is undoped. Multiple VT transistor technology is essential for power vs. performance optimization by circuit designers [6]. In this work, we propose an alternative to conventional FinFET structure which can (a) reduce overall variability by 4× reduction in sensitivity to LER and (b) enable multiple VT by applying body bias dynamically without any costly patterned implant steps.

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外延定义(ED) FinFET:减少VT变异性并实现多个VT

器件可变性已成为CMOS技术的主要关注点。各种可变性的来源包括随机掺杂波动(RDF)，栅极边缘粗糙度(GER)和线边缘粗糙度(LER)[2]。在22nm节点引入finfet有两个问题。首先，由于未掺杂翼b[3]， RDF的影响大大降低。但为了减少短通道效应而要求的大鳍宽(Wfin) (~Lg/3[4])加剧了LER的电影响，使其成为图案诱导变异性[2]的最大贡献者。此外，边缘粗糙度不随技术的变化而变化，与[5]使用的光刻类型无关。其次，在平面技术中，通过各种图像化的植入步骤实现了多个阈值电压(VT)，这在FinFET技术中是不可用的，因为鳍是未掺杂的。多VT晶体管技术对于电路设计人员的功率与性能优化至关重要。在这项工作中，我们提出了一种替代传统FinFET结构的方法，它可以(a)通过将对LER的灵敏度降低4倍来降低整体变异性，(b)通过动态应用体偏置来实现多次VT，而无需任何昂贵的模式植入步骤。

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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70th Device Research Conference

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