Two-dimensional materials for electronic applications

Advanced Nanoelectronics Pub Date : 2018-10-05 DOI:10.1002/9783527811861.CH3

Han Wang

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引用次数: 18

Abstract

The successful isolation of graphene in 2004 has attracted great interest to search for potential applications of this unique material and other members of the two-dimensional materials family in electronics, optoelectronics and their interface with the biological systems. At this early stage of 2D materials research, many opportunities and challenges co-exist in this area. This thesis addresses the following issues which are crucial for 2D electronics to be successful, focusing on developing graphene for RF electronics and MoS2 for digital applications: (1) Development of some of the first graphene-based devices for high frequency applications; (2) Development of compact physical models for graphene transistors; and (3) Understanding the carrier transit delays in graphene transistors. In addition, this thesis proposes and experimentally demonstrates a completely new concept Ambipolar Electronics to take advantage of the unique properties of graphene for RF applications. Based on this new concept, a family of novel applications are developed that can significantly simplify the design of many fundamental building blocks in RF electronics, such as frequency multipliers, mixers and binary phase shift keying devices. In the last part of the thesis, the applications of other emerging 2D materials from the transition metal dichalcogenides family, such as molybdenum disulfide (MoS2), is also explored for potential application in digital electronics, especially as a new material option for high performance flexible electronics. The future opportunities and potential challenges for the applications of the 2D materials family are also discussed. Thesis supervisor: Tomás Palacios Title: Associate Professor of Electrical Engineering

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电子应用的二维材料

2004年石墨烯的成功分离引起了人们对寻找这种独特材料和其他二维材料家族成员在电子学，光电子学及其与生物系统界面中的潜在应用的极大兴趣。在二维材料研究的早期阶段，许多机遇和挑战并存。本文解决了以下问题，这些问题对于二维电子器件的成功至关重要，重点是开发用于射频电子器件的石墨烯和用于数字应用的MoS2:(1)开发一些用于高频应用的第一批基于石墨烯的器件;(2)石墨烯晶体管紧凑物理模型的开发;(3)了解石墨烯晶体管中的载流子传输延迟。此外，本文提出并实验证明了一个全新的概念双极性电子，以利用石墨烯在射频应用中的独特特性。基于这一新概念，开发了一系列新颖的应用程序，可以显着简化射频电子中许多基本构建模块的设计，例如乘频器，混频器和二进制相移键控设备。在论文的最后一部分，还探讨了过渡金属二硫化物家族的其他新兴二维材料的应用，如二硫化钼(MoS2)，在数字电子领域的潜在应用，特别是作为高性能柔性电子产品的新材料选择。讨论了二维材料族应用的未来机遇和潜在挑战。论文导师:Tomás Palacios职称:电子工程副教授

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

Advanced Nanoelectronics

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