碳纳米管场效应晶体管:碳纳米管场效应管低功率高频应用的一个方面

G. Kumar, S. Agrawal
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引用次数: 0

摘要

本文对碳纳米管场效应晶体管(cntfet)高频应用的新方法进行了综述、分析和提出,并基于高频应用的仿真结果进行了验证,这是一种有前景的高性能电子器件技术。由于纳米尺寸,cntfet面临着许多挑战,包括泄漏电流、功耗调节、开关速度和短通道效应(如漏极诱导势垒降低(DIBL)和亚阈值摆幅(SS))等问题。在这方面,低功率CNTFET器件特别令人感兴趣,并将导致现代便携式智能手机和设备中增强和高效的电池寿命。随着对高速、高性能电子器件的需求不断增长,CNTFET技术正在成为一个有前景的研究领域,特别是在5G技术的背景下。这里讨论了各种方法、途径和策略,以解决与设备性能相关的问题。通过分析和讨论这些发表在文献中的新方法,研究人员可以确定提高电子器件性能的最有效策略,包括cntfet。文献中讨论的一些新方法包括使用新型材料制造CNTFET,如石墨烯和其他2D材料,以及开发可以降低功耗和提高开关速度的新器件架构。其他策略包括优化cntfet的增益、掺杂浓度和通道长度(相对于工作频率),以及专注于探索降低泄漏电流和最小化短通道效应的新兴技术。在对当代技术进行比较的基础上,提出了一个一般性的结论。电子固态器件领域的研究人员,特别是那些从事CNTFET电路设计和制造的研究人员,可以从这些发现中受益。索引术语-碳纳米管,场效应晶体管。
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Carbon Nanotube Field Effect Transistors: An Aspect of Low Power and High Frequency Applications of CNTFETs
This paper reviews, analyzes and proposes a new method for high frequency applications of carbon nanotube field effect Transistors (CNTFETs) with validation based of the simulation results for high frequency applications, which are promising technology for High-performance electronic devices. CNTFETs face several challenges due to their nanometer dimensions, including issues with leakage current, power consumption regulation, switching speed, and short channel effects like drain-induced barrier lowering (DIBL) and sub-threshold swing (SS). In this respect Low power CNTFET devices are of particular interest and will result in an enhanced and efficient battery life in modern portable smartphones and devices. With the increasing demand for high-speed and high-performance electronic devices, CNTFET technology is emerging as a promising field of research, especially in the context of 5G technology. Here, various methods, approaches, and strategies have been discussed to address the issues related to the performance of the device. By analyzing and discussing these new approaches published in the literature, researchers can identify the most effective strategies for improving the performance of electronic devices, including CNTFETs. Some of the new approaches that have been discussed in the literature including the use of novel materials for CNTFET Fabrication, such as graphene and other 2D materials, as well as the development of new device architectures that can reduce power consumption and improve switching speed. Other strategies include optimizing the gain, doping concentration and channel length of CNTFETs with respect to the operating frequency along with a dedicated emphasis on exploring the nascent techniques to reduce leakage current and minimize short-channel effects. A general conclusion is also presented that is based on comparison of contemporary technologies. Researchers in the field of electronic solid state devices, especially those working on CNTFET circuit design and fabrication, could benefit from these findings. Index Terms— Carbon Nanotubes, field-effect transistor.
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