光门控CNTFET紧凑模型，包括源和漏肖特基势垒

5th International Conference on Design & Technology of Integrated Systems in Nanoscale Era Pub Date : 2010-03-23 DOI:10.1109/DTIS.2010.5487554

Si-Yu Liao, M. Najari, C. Maneux, S. Frégonèse, T. Zimmer, H. Mnif, N. Masmoudi

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引用次数: 2

摘要

纳米电子电路设计流程是基于器件描述，通过设计器件库中的紧凑模型来实现的。通过研究器件中电子的捕获-去捕获效应，我们开发了一个紧凑的光门控CNTFET模型。这种紧凑的模型代表了传统CNTFET模型已经发布的重要增强。特别地，它包括器件操作的光学写入、电复位和非易失性存储器效应。此外，还描述了源侧和漏侧肖特基势垒金属-碳纳米管接触对器件性能的影响。我们还证明了使用该紧凑模型得到的模拟结果与初步实验测量结果非常吻合。此外，瞬态模拟预测了肖特基势垒对存储器操作的影响。

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Optically-Gated CNTFET compact model including source and drain Schottky barrier

Nanoelectronic circuit design flow is based on device description through the compact models available in the designer device library. We have developed a compact model for the Optically-Gated CNTFET by investigating the trapping-detrapping of electron effects in the device. This compact model represents an important enhancement of conventional CNTFET models already released. Especially, it includes the optical writing, the electrical reset, and the non-volatile memory effect of the device operations. Moreover, it describes also the influence of the device performances of the Schottky barrier metal-CNT contact at the source and drain side. We also demonstrate that the simulation results obtained using this compact model, are in close agreement with preliminary experimental measurements. Furthermore, transient simulations predict the Schottky barrier impact on the memory operation.

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5th International Conference on Design & Technology of Integrated Systems in Nanoscale Era

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