Compact modeling of Fe-FET and implications on variation-insensitive design

2010 International Conference on Simulation of Semiconductor Processes and Devices Pub Date : 2010-10-14 DOI:10.1109/SISPAD.2010.5604516

Chi-Chao Wang, Y. Ye, Yu Cao

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引用次数: 10

Abstract

Semiconductor devices with self-feedback mechanisms are considered as a promising alternative to traditional CMOS, in order to achieve faster operation and lower switching energy. Examples include IMOS and FBFET that are operated in a non-equilibrium condition to rapidly generate mobile carriers [1–2]. More recently, Fe-FET was proposed to improve the switching by integrating a ferroelectric material as gate insulator in a MOSFET structure [3–5]. Under particular circumstance, ferroelectric capacitance is effectively negative, due to the negative slope of its polarization-electrical field (P-E) curve. This property makes the ferroelectric layer a voltage amplifier to boost surface potential, achieving fast transition. In this paper: (1) A new threshold voltage model is developed to capture the feedback of negative capacitance and IV characteristics of Fe-FET; (2) It is further revealed that the impact of random dopant fluctuation (RDF) on leakage variability can be significantly suppressed in Fe-FET, by tuning the thickness of the ferroelectric layer.

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Fe-FET的紧凑建模及其对变化不敏感设计的启示

具有自反馈机制的半导体器件被认为是传统CMOS的一个有前途的替代品，以实现更快的操作和更低的开关能量。例子包括在非平衡条件下运行以快速生成移动载波的IMOS和FBFET[1-2]。最近，Fe-FET被提出通过在MOSFET结构中集成铁电材料作为栅极绝缘体来改善开关[3-5]。在特定情况下，由于其极化电场(P-E)曲线的负斜率，铁电容量实际上是负的。这种特性使铁电层成为一个电压放大器，以提高表面电位，实现快速过渡。本文:(1)建立了一种新的阈值电压模型来捕捉Fe-FET的负电容反馈和IV特性;(2)在Fe-FET中，通过调节铁电层厚度，可以显著抑制随机掺杂波动(RDF)对漏变率的影响。

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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2010 International Conference on Simulation of Semiconductor Processes and Devices

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