Investigating the behavior of physical defects in pn-junction based reconfigurable graphene devices

2013 14th Latin American Test Workshop - LATW Pub Date : 2013-04-03 DOI:10.1109/LATW.2013.6562674

S. Miryala, A. Calimera, E. Macii, M. Poncino, L. Bolzani

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引用次数: 5

Abstract

Graphene, one of the viable candidates to replace Silicon in the next generation electronic devices, is pushing the research community to find new technological solutions that can exploit its special characteristics. Among the proposed approaches, the electrostatic doping represents a key option. It allows the implementation of equivalent pn-junctions through which is possible to build a new class of reconfigurable logic gates, the devices analyzed in this work. Recent works presented a quantitative analysis of such gates in terms of area, delay and power consumptions, confirming their superiority w.r.t. CMOS technologies below the 22nm. This work explores another dimension, that is testability, and proposes a study of possible physical defects that might alter the functionality of the graphene logic gates. The electrical behavior of faulty devices, obtained through the emulation of physical failures at the SPICE-level, has been analyzed and mapped at a higher level of abstraction using proper fault models. Most of such models belong to the CMOS domain, but for some specific class of defects, new fault definitions are needed.

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研究基于pn结的可重构石墨烯器件中物理缺陷的行为

石墨烯是下一代电子设备中取代硅的可行候选材料之一，它正在推动研究界寻找能够利用其特殊特性的新技术解决方案。在提出的方法中，静电掺杂是一个关键的选择。它允许实现等效的pn结，通过它可以构建一类新的可重构逻辑门，在这项工作中分析了器件。最近的工作从面积、延迟和功耗方面对这种栅极进行了定量分析，证实了它们在22nm以下的w.r.t CMOS技术的优越性。这项工作探索了另一个维度，即可测试性，并提出了一项可能改变石墨烯逻辑门功能的物理缺陷的研究。通过spice级物理故障仿真获得的故障设备的电气行为，使用适当的故障模型在更高的抽象级别上进行了分析和映射。这些模型大多属于CMOS领域，但对于某些特定类型的缺陷，需要新的故障定义。

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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2013 14th Latin American Test Workshop - LATW

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