针对低功耗应用的32nm以下CMOS技术增强

2009 International Symposium on VLSI Technology, Systems, and Applications Pub Date : 2009-04-27 DOI:10.1109/VTSA.2009.5159303

R. Huang, P. W. Liu, E. C. Liu, W. Chiang, S. Tsai, J. Tsai, T. Shen, C. Tsai, C. Tsai, G. H. Ma

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摘要

在本文中，我们系统地研究了sub-32nm CMOS技术性能提升的因素。我们报道了PMOS通过超薄间隔获得驱动电流，通过e-SiGe降低S/D硅化电阻，以及压缩CESL。这三个因素分别使PMOS的性能提高了7%、10%和25%。结合这三个因素可以获得器件驱动电流的30%。此外，优化后的集成方案可以降低NMOS的扩展阻力。其主要原因是e-SiGe后的清洁过程会使延伸掺杂剂丢失，从而增加延伸阻力。在不影响PMOS器件性能的情况下，我们成功地将NMOS总电阻降低了22%。

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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Sub-32nm CMOS technology enhancement for low power applications

In this paper, we have systematically investigated the factors for performance enhancement on sub-32nm CMOS technology. We report that PMOS gains the drive current by slim spacer, S/D silicide resistance reduction by e-SiGe, and compressive CESL. The three factors improve the PMOS performance by 7%, 10% and 25% respectively. Combined with the three factors can gain the device drive current 30%. In addition, the optimized integration scheme can reduce NMOS extension resistance. The main cause is that post e-SiGe clean processes would loss the extension dopant and increases the extension resistance. We successfully reduce the NMOS total resistance 22% compared to control without compromise PMOS device performance.

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2009 International Symposium on VLSI Technology, Systems, and Applications

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