Vertically stacked nanowire MOSFETs for sub-10nm nodes: Advanced topography, device, variability, and reliability simulations

2016 IEEE International Electron Devices Meeting (IEDM) Pub Date : 2016-12-01 DOI:10.1109/IEDM.2016.7838516

M. Karner, O. Baumgartner, Z. Stanojevic, F. Schanovsky, G. Strof, C. Kernstock, H. Karner, G. Rzepa, T. Grasset

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引用次数: 26

Abstract

Using an advanced simulation framework we analyze a recent sub-10 nm technology demonstration based on stacked nanowire transistors (NW-FETs). The study encompasses (i) topography simulation which realistically reproduces the fabricated device, (ii) device simulation based on the subband Boltzmann transport equation (iii) a comprehensive set of scattering models for the gate stack, (iv) physical models for time-zero variability and BTI device degradation. We find that (i) the fabrication process introduces parasitic capacitances not present in a comparable FinFET, (ii) the device performance is significantly affected by interface-charge-induced Coulomb scattering resulting in up to 50% reduction in drain current compared to an ideal device, (iii) device time-zero variability is increased due to a lower amount of dopant atoms per device, (iv) the device is more affected by BTI than a comparable FinFET. Using physics-based TCAD for technology path-finding and device optimization, we are able to point out critical improvements required for the stacked NW-FET to surpass current FinFET technology.

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用于亚10nm节点的垂直堆叠纳米线mosfet:先进的地形，器件，可变性和可靠性模拟

利用先进的仿真框架，我们分析了最近基于堆叠纳米线晶体管(nw - fet)的亚10纳米技术演示。该研究包括(i)真实再现制造器件的地形模拟，(ii)基于子带玻尔兹曼输运方程的器件模拟，(iii)栅极堆栈的综合散射模型，(iv)时间零变变性和BTI器件退化的物理模型。我们发现(i)制造过程引入了可比较的FinFET中不存在的寄生电容，(ii)与理想器件相比，器件性能受到界面电荷诱导的库仑散射的显著影响，导致漏极电流减少高达50%，(iii)由于每个器件的掺杂原子量较低，器件时间零可变性增加，(iv)器件受BTI的影响比可比较的FinFET更大。使用基于物理的TCAD进行技术寻径和器件优化，我们能够指出堆叠NW-FET超越当前FinFET技术所需的关键改进。

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 IEEE International Electron Devices Meeting (IEDM)

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