Department of Electrical & Computer Engineering , Duke University , Durham , North Carolina 27708 , United States.
Illumina Inc. , 5200 Illumina Way , San Diego , California 92122 , United States.
Nano Lett. 2019 Mar 13;19(3):1460-1466. doi: 10.1021/acs.nanolett.8b03986. Epub 2019 Feb 8.
Thousands of reports have demonstrated the exceptional performance of sensors based on carbon nanotube (CNT) transistors, with promises of transformative impact. Yet, the effect of long-term bias stress on individual CNTs, critical for most sensing applications, has remained uncertain. Here, we report bias ranges under which CNT transistors can operate continuously for months or more without degradation. Using a custom characterization system, the impacts of defect formation and charge traps on the stability of CNT-based sensors under extended bias are determined. In addition to breakdown, which is well-known, we identify three additional operational modes: full stability, slow decay, and fast decay. We identify a current drift behavior that reduces dynamic range by over four orders of magnitude but is avoidable with appropriate sensing modalities. Identification of these stable operation modes and limits for nanotube-based sensors addresses concerns surrounding their development for a myriad of sensing applications.
数千份报告证明了基于碳纳米管(CNT)晶体管的传感器具有出色的性能,有望带来变革性的影响。然而,对于大多数传感应用至关重要的单个 CNT 长期偏置应力的影响仍然不确定。在这里,我们报告了 CNT 晶体管可以在没有退化的情况下连续运行数月甚至更长时间的偏置范围。使用定制的表征系统,确定了在扩展偏置下缺陷形成和电荷陷阱对基于 CNT 的传感器稳定性的影响。除了众所周知的击穿之外,我们还确定了另外三种工作模式:完全稳定、缓慢衰减和快速衰减。我们发现了一种电流漂移行为,它将动态范围降低了四个数量级以上,但可以通过适当的传感模式来避免。确定这些稳定的工作模式和基于纳米管的传感器的限制,可以解决围绕它们在众多传感应用中发展的问题。
