Aggressively scaled strained silicon directly on insulator (SSDOI) FinFETs

2013 IEEE SOI-3D-Subthreshold Microelectronics Technology Unified Conference (S3S) Pub Date : 1900-01-01 DOI:10.1109/S3S.2013.6716520

A. Khakifirooz, R. Sreenivasan, B. Taber, F. Allibert, P. Hashemi, W. Chern, N. Xu, E. C. Wall, S. Mochizuki, J. Li, Y. Yin, N. Loubet, A. Reznicek, S. Mignot, D. Lu, H. He, T. Yamashita, P. Morin, G. Tsutsui, C. Chen, V. Basker, T. Standaert, K. Cheng, T. Levin, B. Nguyen, Tsu-Jae King Liu, D. Guo, H. Bu, K. Rim, B. Doris

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引用次数: 7

Abstract

Strain engineering has been in the heart of CMOS technology for over a decade. However, the effectiveness of conventional strain elements, such as stress liners, embedded S/D stressors, and stress memorization, is significantly reduced when device gate pitch is scaled below 100 nm as needed for 14nm node and beyond. Substrate strain engineering, where the channel itself is formed out of a strained semiconductor, e.g. in the form of strained silicon directly on insulator (SSDOI) or strained SiGe-on-insulator has the advantage that the strain is independent of the device pitch or gate length as long as the active region is made sufficiently long and the strain is maintained throughout the device processing. We have already shown that in a FinFET structure the starting biaxial strain in the SSDOI substrate is converted to a more beneficial uniaxial strain, strain can be maintained throughout typical thermal processing, and demonstrated roughly 15% increase in NFET performance in deeply scaled FinFETs. However, this is still far less than the performance gain we reported recently in ETSOI devices. In this work, for the first time we report NFET performance gain in SSDOI FinFETs fabricated with contacted gate pitch (CGP) down to 64nm.

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积极缩放应变硅直接对绝缘体(SSDOI) finfet

十多年来，应变工程一直是CMOS技术的核心。然而，当器件栅极间距小于100 nm以满足14nm及以上节点的需求时，传统应变元件(如应力衬垫、嵌入式S/D应力源和应力记忆)的有效性将显著降低。衬底应变工程，其中通道本身是由应变半导体形成的，例如，在绝缘体上直接应变硅(SSDOI)或绝缘体上应变硅的形式，其优点是，只要有源区域足够长并且在整个器件加工过程中保持应变，应变与器件节距或栅极长度无关。我们已经证明，在FinFET结构中，SSDOI衬底中的起始双轴应变转换为更有利的单轴应变，应变可以在典型的热处理过程中保持不变，并且在深度缩放FinFET中显示了大约15%的NFET性能提高。然而，这仍然远远低于我们最近在ETSOI设备中报告的性能增益。在这项工作中，我们首次报道了接触栅极间距(CGP)降至64nm的SSDOI finfet的NFET性能增益。

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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2013 IEEE SOI-3D-Subthreshold Microelectronics Technology Unified Conference (S3S)

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