Density scaling beyond the FinFET: Architecture considerations for gate-all-around CMOS

2016 74th Annual Device Research Conference (DRC) Pub Date : 2016-06-19 DOI:10.1109/DRC.2016.7548399

M. Guillorn, N. Loubet, C. Yeung, R. Chao, R. Muthinti, J. Demarest, R. Robison, Xin He Miao, Jingyun Zhang, T. Hook, P. Oldiges, T. Yamashita

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引用次数: 2

Abstract

The promise of improved electrostatics and the ability to increase the amount of effective width (Weff) available in a given device footprint drove the semiconductor industry from planar CMOS transistors to the FinFET transistor starting at the 22 nm node. Numerous manufacturers are in large-scale production of 16 and 14 nm node FinFET technologies and there is no indication that a change in device architecture is planned for the 10 or 7 nm nodes. Looking beyond 7 nm, the scaling challenges of the FinFET are expected to increase dramatically. In particular, continued scaling of the fin width and fin pitch may reach a physical limit due to a combination of quantum effects, patterning process realities and contact architecture limitations. It is well known that gate-all-around (GAA) devices demonstrate improved electrostatics over double or triple-gated FinFET devices. In view of the impending difficulties occasioned by FinFET scaling, it is necessary to take a critical look at the possibility of a GAA CMOS device technology. In this paper, I will explore this topic by presenting relevant TCAD and experimental work on single and stacked GAA devices. The TCAD illustrates that a properly designed stacked GAA device architecture can show superior performance over a scaled FinFET reference. I will conclude by presenting experimental work to substantiate this claim.

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超越FinFET的密度缩放:栅极全能CMOS的架构考虑

改善静电性能的前景，以及在给定器件占地面积内增加有效宽度(Weff)的能力，推动半导体行业从平面CMOS晶体管转向从22纳米节点开始的FinFET晶体管。许多制造商正在大规模生产16和14纳米节点FinFET技术，并且没有迹象表明计划在10或7纳米节点上改变器件架构。展望7nm之后，FinFET的缩放挑战预计将急剧增加。特别是，由于量子效应、图像化过程的现实和接触结构的限制，翅片宽度和翅片间距的持续缩放可能达到物理极限。众所周知，栅极全能(GAA)器件比双门或三门FinFET器件具有更好的静电性能。鉴于FinFET缩放所带来的迫在眉睫的困难，有必要对GAA CMOS器件技术的可能性进行批判性的研究。在本文中，我将通过介绍在单个和堆叠GAA器件上的相关TCAD和实验工作来探索这个主题。TCAD表明，适当设计的堆叠GAA器件架构可以显示出比缩放FinFET基准更高的性能。最后，我将提出实验工作来证实这一说法。

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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2016 74th Annual Device Research Conference (DRC)

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