Quasi-Ohmic Single Molecule Charge Transport through Highly Conjugated meso-to-meso Ethyne-Bridged Porphyrin Wires
Author(s):
Zhihai Li, Tae-Hong Park, Jeff Rawson, Michael J. Therien, Eric Borguet
Journal:
Nano Letters
Year:
2012
Volume:
12
Pages
2722−2727
DOI:
10.1021/nl2043216
Abstract:
Understanding and controlling electron transport through functional molecules are of primary importance to the development of molecular scale devices. In this work, the single molecule resistances of meso-to-meso ethyne-bridged (porphinato)zinc(II) structures (PZnn compounds), connected to gold electrodes via (4′-thiophenyl)ethynyl termini, are determined using scanning tunneling microscopy-based break junction methods. These experiments show that each α,ω-di[(4′-thiophenyl)ethynyl]-terminated PZnn compound (dithiol-PZnn) manifests a dual molecular conductance. In both the high and low conductance regimes, the measured resistance across these metal−dithiol-PZnn−metal junctions increases in a near linear fashion with molecule length. These results signal that meso-to-meso ethyne-bridged porphyrin wires afford the lowest β value (β = 0.034 Å−1 ) yet determined for thiol-terminated single molecules that manifest a quasi-ohmic resistance dependence across metal−dithiol-PZnn−metal junctions.