测试分子器件在CMOS/纳米集成电路

P. Paliwoda, D.S. Maragal, G. Rose
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引用次数: 0

摘要

由于CMOS的限制越来越严格,分子电子学可以提高电路的速度和密度。然而,由于制造分子电路的困难,最初使用由分子和CMOS元件组成的混合模型可能是有益的。这种器件的分子特征尺寸可以产生高密度存储器应用,预计可达到1011 b/cm2。这种系统的缺陷率预计为10%,但由于开销的原因,它仍然是一种有吸引力的技术。本文的目的是研究在分子电子结构中检测缺陷的技术。从本质上讲,所提出的技术将导致系统在最小内存损失的情况下自我修复,从而提高制造内存的可靠性和实用性。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Testing molecular devices in CMOS/nano integrated circuits
Molecular electronics may improve the speed and density of circuits as the limitations of CMOS become more stringent. However, due to the difficulties in manufacturing molecular circuits, it may be beneficial to use a hybrid model initially, composed of both molecular and CMOS components. The molecular feature size of such devices can yield high density memory applications, which are expected to reach 1011 b/cm2. The defect rate in such systems is expected to be 10%, which still makes it an attractive technology due to overhead. The goal of this paper is to investigate techniques of detecting defects within molecular electronic structures. Essentially, the proposed techniques will lead to systems that are self-healing with minimal loss of memory improving the reliability and the utility of the manufactured memory.
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