纳米双栅垂直MOSFET非对称漏源/源极拓扑的性能比较

2013 International Conference on Information Technology and Electrical Engineering (ICITEE) Pub Date : 2013-12-02 DOI:10.1109/ICITEED.2013.6676285

M. Riyadi

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引用次数: 1

摘要

双栅MOSFET结构是一种很有前途的纳米级先进器件结构。本文采用数值分析的方法，阐述了以ORI方法作为源极/漏极制造技术的垂直双栅MOSFET (VDGM)的非对称拓扑结构。分析了漏极顶(DOT)和源极顶(SOT)拓扑的电特性，特别是亚阈值性能，观察了器件的短通道效应(SCE)。结果表明，减小硅柱厚度可提高DIBL性能，阈值电压滚降随硅柱厚度的变化程度基本相同。在SOT中，较厚的硅柱可能会出现浮体效应，因为漏极的耗尽层在衬底和柱区之间形成了更深的屏障。亚阈值斜率的性能比较表明，在短通道长度为30 nm时，较低硅厚的DOT拓扑结构具有更好的SCE控制。

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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Performance comparison of asymmetric drain/source topology in nanoscale Double Gate vertical MOSFET

Double Gate MOSFET structure is a promising architecture for advanced devices in nanometer regime. This paper elaborates the asymmetric topology of Vertical Double Gate MOSFET (VDGM) with ORI method as source/drain fabricating technique using numerical analysis approach. The electrical characteristics of the drain-on-top (DOT) and source-on-top (SOT) topology were analyzed, especially in the sub-threshold performance, to observe the short channel effect (SCE) of the device. The result shows that silicon pillar thickness reduction enhance the DIBL performance, while the threshold voltage roll-off change in nearly the same degree with the thickness variation. The floating body effect will likely occur for thicker silicon pillar in SOT, as the drain's depletion layer creates deeper barrier between substrate and pillar region. The performance comparison of sub-threshold slope revealed better SCE control for DOT topology in the lower silicon thickness for short channel length up to 30 nm.

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2013 International Conference on Information Technology and Electrical Engineering (ICITEE)

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