Current voltage characteristics of Carbon Nano Tube Field Effect Transistor

Recent Advances in Space Technology Services and Climate Change 2010 (RSTS & CC-2010) Pub Date : 2010-11-01 DOI:10.1109/RSTSCC.2010.5712860

Y. Varthamanan, V. Kannan

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引用次数: 2

Abstract

Carbon Nanotube Field Effect Transistors (CNTFET) are promising nano-scaled devices for implementing high performance, very dense and low power circuits. The core of a CNTFET is a carbon nanotube. Its conductance property is determined by the so-called chirality of the tube; chirality is difficult to control during manufacturing. This results in conducting (metallic) nanotubes and defective CNTFETs similar to stuck-on (SON or source-drain short)faults, as encountered in classical MOS devices. This paper studies this phenomenon by using layout information and presents modeling. For CNTFET-based circuits (e.g. intramolecular), these defects are analyzed using a traditional stuck-at fault model. This analysis is applicable to primitive and complex gates. In this paper, we have also developed a simple analytical model for ballistic nano transistors that operate by modulating the charge in the device (as opposed to modulating the current at the contact). This analytical model captures the essential physics of MOSFET-like ballistic[10] nanotransistors and provides a convenient way to assess and compare transistors at the ballistic limit. The circuit simulation was carried out using SPICE model and the current voltage characteristics were obtained.

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碳纳米管场效应晶体管的电流电压特性

碳纳米管场效应晶体管(CNTFET)是实现高性能、高密度和低功耗电路的有前途的纳米器件。碳纳米管的核心是碳纳米管。它的导电性是由所谓的管的手性决定的;手性是制造过程中难以控制的问题。这导致导电(金属)纳米管和有缺陷的cntfet类似于在经典MOS器件中遇到的粘接(SON或源漏短路)故障。本文利用布局信息对这一现象进行了研究，并建立了模型。对于基于cntfet的电路(例如分子内电路)，使用传统的卡滞故障模型来分析这些缺陷。这种分析适用于原始门和复杂门。在本文中，我们还为弹道纳米晶体管开发了一个简单的分析模型，该模型通过调制器件中的电荷(而不是调制触点处的电流)来工作。该分析模型捕获了类mosfet弹道[10]纳米晶体管的基本物理特性，并提供了一种方便的方法来评估和比较弹道极限下的晶体管。利用SPICE模型对电路进行仿真，得到了电流电压特性。

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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来源期刊

Recent Advances in Space Technology Services and Climate Change 2010 (RSTS & CC-2010)

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