Dynamic admittance of carbon nanotube-based molecular electronic devices and their equivalent electric circuit

Chi Yung Yam; Yan Mo; Fan Wang; Xiaobo Li; Guan Hua Chen; Xiao Zheng; Yuki Matsuda; Jamil Tahir-Kheli; William A. Goddard

doi:10.1088/0957-4484/19/49/495203

Dynamic admittance of carbon nanotube-based molecular electronic devices and their equivalent electric circuit

Chi Yung Yam^*
, Yan Mo
, Fan Wang
, Xiaobo Li
, Guan Hua Chen
, Xiao Zheng
, Yuki Matsuda
, Jamil Tahir-Kheli
, William A. Goddard

^*此作品的通讯作者

The University of Hong Kong
Hong Kong University of Science and Technology
California Institute of Technology

科研成果: 期刊稿件 › 文章 › 同行评审

45 引用（Scopus）

摘要

We use first-principles quantum mechanics to simulate the transient electrical response through carbon nanotube-based conductors under time-dependent bias voltages. The dynamic admittance and time-dependent charge distribution are reported and analyzed. We find that the electrical response of these two-terminal molecular devices can be mapped onto an equivalent classical electric circuit and that the switching time of these end-on carbon nanotube devices is only a few femtoseconds. This result is confirmed by studying the electric response of a simple two-site model device and is thus generalized to other two-terminal molecular electronic devices.

源语言	英语
文章编号	495203
期刊	Nanotechnology
卷	19
期	49
DOI	https://doi.org/10.1088/0957-4484/19/49/495203
出版状态	已出版 - 10 12月 2008
已对外发布	是

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abstract = "We use first-principles quantum mechanics to simulate the transient electrical response through carbon nanotube-based conductors under time-dependent bias voltages. The dynamic admittance and time-dependent charge distribution are reported and analyzed. We find that the electrical response of these two-terminal molecular devices can be mapped onto an equivalent classical electric circuit and that the switching time of these end-on carbon nanotube devices is only a few femtoseconds. This result is confirmed by studying the electric response of a simple two-site model device and is thus generalized to other two-terminal molecular electronic devices.",

author = "Yam, \{Chi Yung\} and Yan Mo and Fan Wang and Xiaobo Li and Chen, \{Guan Hua\} and Xiao Zheng and Yuki Matsuda and Jamil Tahir-Kheli and Goddard, \{William A.\}",

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AU - Yam, Chi Yung

AU - Mo, Yan

AU - Wang, Fan

AU - Li, Xiaobo

AU - Chen, Guan Hua

AU - Zheng, Xiao

AU - Matsuda, Yuki

AU - Tahir-Kheli, Jamil

AU - Goddard, William A.

PY - 2008/12/10

Y1 - 2008/12/10

N2 - We use first-principles quantum mechanics to simulate the transient electrical response through carbon nanotube-based conductors under time-dependent bias voltages. The dynamic admittance and time-dependent charge distribution are reported and analyzed. We find that the electrical response of these two-terminal molecular devices can be mapped onto an equivalent classical electric circuit and that the switching time of these end-on carbon nanotube devices is only a few femtoseconds. This result is confirmed by studying the electric response of a simple two-site model device and is thus generalized to other two-terminal molecular electronic devices.

AB - We use first-principles quantum mechanics to simulate the transient electrical response through carbon nanotube-based conductors under time-dependent bias voltages. The dynamic admittance and time-dependent charge distribution are reported and analyzed. We find that the electrical response of these two-terminal molecular devices can be mapped onto an equivalent classical electric circuit and that the switching time of these end-on carbon nanotube devices is only a few femtoseconds. This result is confirmed by studying the electric response of a simple two-site model device and is thus generalized to other two-terminal molecular electronic devices.

UR - https://www.scopus.com/pages/publications/58149248051

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SN - 0957-4484

VL - 19

JO - Nanotechnology

JF - Nanotechnology

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M1 - 495203

ER -

Dynamic admittance of carbon nanotube-based molecular electronic devices and their equivalent electric circuit

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