超低功耗计算和超大规模集成电路的纳米机电系统

P. Feng
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引用次数: 0

摘要

具有机械自由度的纳米级器件提供了令人信服的特性,使其对机械和量子逻辑器件非常有吸引力。由于我们能够创建具有前所未有的特征尺寸,先进的复杂性和功能,以及高产量和控制(在晶圆级)的纳米机电系统(NEMS),它们对于低功耗逻辑和存储器变得越来越有趣,并且对VLSI变得更有意义。这在一定程度上是由于NEMS器件的独特优点,如超大的开/关比,无泄漏,超低开关功率,快速和温度不敏感。与此同时,这也是一项有趣的努力,旨在寻求逻辑和计算的最终节能实现。在这次演讲中,我将介绍加州理工学院为实现这些目标所做的研究工作,包括最近几种纳米级机电开关器件的通用原型的演示,它们的特性和性能,基于nems的逻辑和存储器,全机械和混合NEMS-CMOS的工程构建块的进展,以及技术承诺和挑战的讨论和观点。
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Nanoelectromechanical systems for ultra-low-power computing and VLSI
Nanoscale devices with mechanical degrees of freedom offer compelling characteristics that make them very attractive for mechanical and quantum logic devices. As we are able to create nanoelectromechanical systems (NEMS) with unprecedented feature sizes, advanced complexity and functionality, and high yield and control (at wafer-scale), they become increasingly interesting for low-power logic and memory, as well as become more meaningful for VLSI. Partly this is driven by NEMS devices' unique merits such as exceptionally large on/off ratio, non-leakage, ultralow switching power, fast speed, and temperature insensitivity. In parallel, this is also an intriguing effort in the quest for the ultimately energy-efficient implementation of logic and computing. In this talk, I shall introduce the Caltech research effort towards these goals, including the recent demonstrations of several generic prototypes of nanoscale electromechanical switching devices, their characteristics and performance, progress on engineering such building blocks for NEMS-based logic and memory, all-mechanical and hybrid NEMS-CMOS, along with discussions and perspectives of technological promises and challenges.
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