Single-Molecule Conductance of Pyridine-Terminated Dithienylethene Switch Molecules
Author(s):
Eugenia S. Tam, Joshua J. Parks, William W. Shum, Yu-Wu Zhong, Mitk’El B. Santiago-Berríos, Xiao Zheng, Weitao Yang, Garnet K.-L. Chan, Héctor D. Abruña, Daniel C. Ralph
Journal:
ACS Nano
Year:
2011
Volume:
5
Pages
5115-5123
DOI:
10.1021/nn201199b
Abstract:
We have investigated the conductance of individual optically switchable dithienylethene molecules in both their conducting closed configuration and nonconducting open
configuration, using the technique of repeatedly formed break-junctions. We employed pyridine groups to link the molecules to gold electrodes in order to achieve relatively well-defined molecular contacts and stable conductance. For the closed form of each molecule, we observed a peak in the conductance histogram constructed without any data selection, allowing us to determine the conductance of the fully stretched molecules. For two different dithienylethene derivatives, these closed-configuration conductances were (3.3 ( 0.5) 105 G0 and (1.5 ( 0.5) 106 G0, where G0 is the conductance quantum. For the open configuration of the molecules, the existence of electrical conduction via the molecule was evident in traces of conductance versus junction displacement, but the conductance of the fully stretched molecules was less than the noise floor of our measurement. We can set a lower limit of 30 for the on/off ratio for the simplest dithienylethene derivative we have investigated. Density functional theory calculations predict an on/off ratio consistent with this result.