Y. Lin, J. Appenzeller, C. Tsuei, Z. Chen, P. Avouris
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引用次数: 2
摘要
YU-MING LIN, PHAEDON AVOURIS, IBM t.j. Watson研究中心- 1/f噪声是半导体和金属中普遍存在的波动。与热噪声和弹丸噪声等其他类型的波动不同,1/f噪声随着器件尺寸的减小而增加,并且高度依赖于材料质量和界面特性。因此,纳米器件的噪声特性通常以1/f型波动为主。本文对单壁碳纳米管构成的碳纳米管器件的1/f噪声进行了系统的研究。为了降低碳纳米管器件的1/f噪声水平,我们研究了接触和衬底对1/f噪声的影响。通过消除与氧化物衬底相关的电荷陷阱,我们发现碳纳米管器件中的1/f噪声可以降低两个数量级。这些结果揭示了碳纳米管器件中1/f噪声源的重要影响因素,对基于碳纳米管的应用具有重要意义。提交日期:2006年11月20日电子表格1.4版
Submitted for the MAR07 Meeting of The American Physical Society Characterization and Reduction of 1/f Noise in Carbon Nanotube Devices YU-MING LIN, PHAEDON AVOURIS, IBM T. J. Watson Research Center — 1/f noise is a ubiquitous fluctuation in semiconductors and metals. Unlike other types of fluctuations such as the thermal noise and the shot noise, 1/f noise increases with decreasing device dimension and is highly dependent on the material quality and interface properties. Therefore, the noise characteristics in nanoscaled devices are usually dominated by the 1/f-type fluctuations. Here we perform a systematic study on the 1/f noise of carbon nanotube devices consisting of individual single-wall carbon nanotubes. We have examined the impact of the contact and the substrate to the 1/f noise in carbon nanotube devices in order to reduce the 1/f noise level. By eliminating the charge traps associated with oxide substrates, we found that the 1/f noise in carbon nanotube devices can be lowered by up to two orders of magnitude. These results reveal important factors contributing to the 1/f noise source in carbon nanotube devices, and are of great importance for applications based on carbon nanotubes. Yu-Ming Lin IBM T. J. Watson Research Center Date submitted: 20 Nov 2006 Electronic form version 1.4
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