Switching limits in nano-electronic devices

10th IEEE International Conference on Nanotechnology Pub Date : 2010-08-01 DOI:10.1109/NANO.2010.5697728

Lijun Li, D. Unluer, M. Kabir, F. Tseng, M. Stan, Avik W. Ghosh

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引用次数: 2

Abstract

Present day CMOS transistors operate by thermionic emission of electrons over a gate tunable barrier. The fundamental switching energy for each such switching event can be derived from equilibrium thermodynamic considerations. While clever ways can sometimes mitigate the power budget, more often than not, this involves trade-offs with short channel effects (variability), on-off ratio (reliability) and mobility (switching speed). We discuss switching paradigms that venture beyond the near-equilibrium operation of transistors involving the absence or presence of charges as the digital switching bits. To this end, a few case studies are presented. Dipolar switching is invoked as an example to show how gating non-electronic degrees of freedom can reduce the subthreshold swing below the textbook limit by acting as an added cut-off filter on the current. We discuss how new state variables may be engineered into a CMOS platform to enable such non-electronic switching. Another, completely different direction involves non-equilibrium switching, such as a ratchet that allows us to move charges unidirectionally without a drain bias, by using instead an always present AC clock signal adiabatically coupled with the gate.

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纳米电子器件中的开关限制

目前的CMOS晶体管是通过栅极可调谐势垒上的电子热电子发射来工作的。每个这样的开关事件的基本开关能量可以从平衡热力学的考虑推导出来。虽然聪明的方法有时可以减轻功率预算，但通常情况下，这涉及到短通道效应(可变性)、开关比(可靠性)和移动性(切换速度)之间的权衡。我们讨论的开关范式，冒险超越近平衡操作的晶体管涉及没有或存在的电荷作为数字开关位。为此，提出了几个案例研究。偶极开关作为一个例子，以显示门控非电子自由度如何通过作为电流的附加截止滤波器，将亚阈值摆幅降低到教科书限制以下。我们讨论了如何将新的状态变量设计到CMOS平台中以实现这种非电子开关。另一个完全不同的方向涉及非平衡开关，例如棘轮，它允许我们在没有漏极偏置的情况下单向移动电荷，而是使用始终存在的交流时钟信号与栅极绝热耦合。

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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10th IEEE International Conference on Nanotechnology

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