纳米弹道MOSFET:数字电路的建模、仿真和应用

2010 XIth International Workshop on Symbolic and Numerical Methods, Modeling and Applications to Circuit Design (SM2ACD) Pub Date : 2010-12-17 DOI:10.1109/SM2ACD.2010.5672358

Mustafa M. El-Muradi, Khalf alla A. Khalf alla, Walid T. Shanab

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引用次数: 4

摘要

提出了一种新的、精确的、简单的弹道区纳米双栅n- MOSFET器件的数值模拟方法。模型和分析是在通道长度小于20nm的情况下进行的，其中电子传输主要是弹道传输。本文提出了一种基于玻尔兹曼输运方程和泊松方程的n沟道纳米双栅MOSFET建模新方法。讨论了弹道输运对基于矩基宏观输运模型的纳米级MOSFET建模的影响。结果表明，当通道长度减小到20nm及以下时，器件性能得到提高。由于它取决于氧化物的厚度和通道掺杂的这些特性使得DG。MOSFET潜在地适用于逻辑电路和数字电路。该模型已应用于环形振荡器、CMOS逆变器等低功耗数字电路的仿真技术中。

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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Nanometer ballistic MOSFET'S: Modeling, simulation and applications of digital circuits

An accurate new and simple numeral modeling of nano-scale dual gate n- MOSFET device in the ballistic region is presented. The model and the analysis is performed with channel length below 20 nm where electron transport is predominantly ballistic. In this paper a new developed modeling approach based on Boltzmann transport equation and Poisson equation in an n-channel nanoscale double-gate MOSFET is provided. The implications of ballistic transport to modeling a nanoscale MOSFET based on moment-based macroscopic transport models are discussed. The results show that the decrease in channel length toward 20nm and below increases the device performance. As it depends on the oxide thickness and the channel doping these characteristics make DG.MOSFET potentially suitable for logic- and digital circuits. The model has been implemented in the circuit simulation techniques such as Ring oscillators, CMOS inverters and other low power digital circuits.

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来源期刊

2010 XIth International Workshop on Symbolic and Numerical Methods, Modeling and Applications to Circuit Design (SM2ACD)

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