对称双栅和环栅MOS晶体管的统一载流子模型

2007 14th International Conference on Mixed Design of Integrated Circuits and Systems Pub Date : 2007-06-21 DOI:10.1109/MIXDES.2007.4286121

J. He, W. Bian, Y. Tao, F. Liu, X. Zhang, W. Wu, T. Wang, M. Chan

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引用次数: 0

摘要

本文扩展了基于载波的建模方法(CBMA)，通过参数变换建立了具有相同数学公式的对称双栅(DG)和环绕栅(SRG) MOS晶体管的统一紧凑模型。统一的模型公式便于用不同的物理解处理不同的器件结构，避免了需要求解不同的基本方程。结果表明，通过适当的参数变换，DG和SRG mosfet在所有偏置范围内，如从亚阈值到强反转区，从线性区到饱和区，都可以得到随硅层厚度和栅极氧化层厚度可扩展的统一溶液公式。特别是DG MOSFET中的“体积反转效应”等非经典MOS器件的独特物理效应，可以用SRG MOSFET模型公式精确地再现。

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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A Unified Carrier-Based Model for Symmetric Double-Gate and Surrounding-Gate MOS Transistors

In this paper, a carrier-based modelling approach (CBMA) is extended to develop a unified compact model for the symmetric double-gate (DG) and surrounding-gate (SRG) MOS transistors with the same mathematic formulation via the parameter transformation. The unified model formulation makes it easy to handle different device structures with different physical solutions, avoiding the need to solve the different fundamental equations. It is shown that it is viable to obtain a unified solution formulation scalable with silicon layer thickness and gate oxide layer in all bias ranges, e.g. from the sub-threshold to the strong inversion and from the linear to the saturation region for the DG and SRG MOSFETs by the means of the appropriate parameter transformation. In particular, the unique physics effect of the non-classical MOS devices such as the "volume inversion effect" in the DG MOSFETs is exactly reproduced by present unified model with the SRG MOSFET model formulation.

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2007 14th International Conference on Mixed Design of Integrated Circuits and Systems

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