Dynamic admittance of carbon nanotube-based molecular electronic devices and their equivalent electric circuit
ChiYung Yam, Yan Mo, Fan Wang, Xiaobao Li, Guanhua Chen, Xiao Zheng, Yuki Matsuda, Jamil Tahir-Kheli, William A. Goddard III
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.
Group Members
Yam, C., Mo, Y., Wang, F., Li, X., Chen, G., Zheng, X., Matsuda, Y., Tahir-Kheli, J., & III, W. A. G. (2008). Dynamic admittance of carbon nanotube-based molecular electronic devices and their equivalent electric circuit. *Nanotechnology*, *19*(49), Art. No. 495203. https://doi.org/10.1088/0957-4484/19/49/495203