量子纳米电子学:挑战与机遇

V. Arora, M. Tan
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引用次数: 4

摘要

经过四十年的集成电路技术的进步,随着2004年90纳米量产的引入,硅金属氧化物半导体场效应晶体管(MOSFET)的规模已经进入纳米尺寸。目前,从45纳米到2009年32纳米节点,最新的技术进步导致了低功耗、高密度和高速的微处理器一代。VLSI电路和器件模拟程序严重依赖于物理定律,随着器件被缩小到纳米级,这些物理定律正在被发现和重新发现。硅MOSFET在22 nm以下的尺度可能很快就会遇到其基本的物理限制。然而,石墨烯、碳纳米管场效应晶体管(cnfet)和纳米线等新型器件和结构为克服性能限制提供了解决方案。对独特的电子和输运特性的清晰理解是至关重要的,因为模拟程序在实施新的发现和参数时总是滞后的,这些发现和参数可能是基于物理的,也可能不是。本文研究了能够在器件和电路模拟中预测纳米结构性能的量子和非欧姆输运现象。提出的想法将使研究人员能够识别输入的物理过程,以形成一个智能的角度来解释所获得的输出。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantum nanoelectronics: Challenges and opportunities
After forty years of advances in integrated circuit technology, the scaling of Silicon Metal Oxide Semiconductor Field Effect Transistor (MOSFET) has entered the nanometer dimension with the introduction of 90 nm high volume manufacturing in 2004. Presently at 45 nm going to 32 nm node in 2009, the latest technological advancement has led to low power, high-density and high-speed generation of microprocessors. VLSI circuit and device simulation programs rely heavily on the laws of physics that are being discovered and re-discovered as devices are being scaled down to nanometer regime. The scaling of the Si MOSFET below 22 nm may soon meet its fundamental physical limitations. Nevertheless, novel devices and structures such as graphene, carbon nanotube field effect transistors (CNFETs) and nanowires offer a solution to overcome the performance limits. A clear understanding of a unique electronics and transport properties is vital as simulation programs always lag behind in implementing new findings and parameters that may or may not be physics-based. This paper examines quantum and nonohmic transport phenomena that are capable of predicting the performance of a nanostructure in device and circuit simulations. The ideas presented will allow researchers to identify the input physical processes to form an intelligent perspective in interpreting the output obtained.
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