严格考虑量子力学效应的MOS结构阈值电压模型

2000 22nd International Conference on Microelectronics. Proceedings (Cat. No.00TH8400) Pub Date : 2000-05-14 DOI:10.1109/ICMEL.2000.840561

Yutao Ma, Zhijian Li, Litian Liu, Z. Yu

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引用次数: 2

摘要

从第一性原理出发，分析了量子力学效应对深亚微米MOSFET特性的影响。在严格考虑子带结构和载波分布的基础上，证明了早期工作中常用的单子带占用近似是无效的。提出了表面层量子有效态密度(SQEDOS)和表面层经典有效态密度(SCEDOS)的概念，并由此导出了由QME引起的v次位移模型。该模型揭示了QME对Vth位移影响的物理性质，并给出了与实验一致的结果。

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MOS structure threshold voltage model by rigorously considering quantum mechanical effect

Quantum Mechanical Effects (QME) on deep-submicron MOSFET characteristics are analyzed from first-principle theory. The single subband occupation approximation often used in earlier works is proved to be invalid, based on rigorous consideration of subband structure and carrier distribution. The concepts of surface layer quantum effective density of states (SQEDOS) and the surface layer classical effective density of states (SCEDOS) are proposed through which a Vth shift model due to QME is derived. The model reveals the physical nature of the influence of QME on the Vth shift and gives consistent results with experiments.

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来源期刊

2000 22nd International Conference on Microelectronics. Proceedings (Cat. No.00TH8400)

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