纳米dg - mosfet性能特性物理参数变化分析

Yashu Swami, Sanjeev Rai
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引用次数: 3

摘要

由于与体mosfet相比,dg - mosfet具有更好的亚阈值斜率和更低的泄漏功率,因此在50 nm以下的无级CMOS电路设计中,dg - mosfet是应用最广泛的器件架构。在薄膜(tsi < 10 nm)的DG-MOS结构中,载流子受到tsi诱导的量子约束以及界面处非常高的电场引起的约束的影响。因此,量子约束效应对器件特性的影响也非常重要,在纳米级电路设计中需要将其与短通道效应结合起来。在本文中,我们分析了在20 nm技术节点上结合量子限制效应和各种短通道效应的DG-MOSFET结构。物理参数变化对器件性能特性的影响,如阈值电压、亚阈值斜率、I on - I OFF比、DIBL等,已经通过广泛的TCAD模拟进行了研究和绘制。本文考虑的物理参数有工作温度(T - op)、通道掺杂浓度(N - c)、栅氧化层厚度(T - ox)和硅膜厚度(T - si)。观察到载流子的量子约束对器件的性能特性(主要是亚阈值特性)有显著影响,因此在基于亚阈值区域的电路设计中,与以往许多研究工作一样,不能忽视量子约束。本文采用ATLAS TM器件模拟器进行仿真和参数提取。手稿中提出的TCAD分析可以用于器件建模和器件匹配。它可以用来说明确切的设备行为和适当的设备控制。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Physical Parameter Variation Analysis on the Performance Characteristics of Nano DG-MOSFETs
DG-MOSFETs are the most widely explored device architectures for na-no-scale CMOS circuit design in sub-50 nm due to the improved subthreshold slope and the reduced leakage power compared to bulk MOSFETs. In thin-film (t si < 10 nm) DG-MOS structures, charge carriers are affected by t si induced quantum confinement along with the confinement caused by a very high electric field at the interface. Therefore, quantum confinement effects on the device characteristics are also quite important and it needs to be incorporated along with short channel effects for nano-scale circuit design. In this paper, we analyzed a DG-MOSFET structure at the 20 nm technology node incorporating quantum confinement effects and various short channel effects. The effect of physical parameter variations on performance characteristics of the device such as threshold voltage, subthreshold slope, I ON - I OFF ratio, DIBL, etc. has been investigated and plotted through extensive TCAD simulations. The physical parameters considered in this paper are operating temperature (T op ), channel doping concentration (N c ), gate oxide thickness (t ox ) and Silicon film thickness (t si ). It was observed that quantum confinement of charge carriers significantly affected the performance characteristics (mostly the subthreshold characteristics) of the device and therefore, it cannot be ignored in the subthreshold region-based circuit design like in many previous research works. The ATLAS TM device simulator has been used in this paper to perform simulation and parameter extraction. The TCAD analysis presented in the manuscript can be incorporated for device modeling and device matching. It can be used to illustrate exact device behavior and for proper device control.
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