posted on 2015-02-18, 00:00authored byPavel Moreno-García, Andrea La Rosa, Viliam Kolivoška, Daniel Bermejo, Wenjing Hong, Koji Yoshida, Masoud Baghernejad, Salvatore Filippone, Peter Broekmann, Thomas Wandlowski, Nazario Martín
Single molecule charge
transport characteristics of buckminsterfullerene-capped
symmetric fluorene-based dumbbell-type compound 1 were
investigated by scanning tunneling microscopy break junction (STM-BJ),
current sensing atomic force microscopy break junction (CS-AFM-BJ),
and mechanically controlled break junction (MCBJ) techniques, under
ambient conditions. We also show that compound 1 is able
to form highly organized defect-free surface adlayers, allowing the
molecules on the surface to be addressed specifically. Two distinct
single molecule conductance states (called high GH1 and low GL1) were observed, depending on the
pressure exerted by the probe on the junction, thus allowing molecule 1 to function as a mechanically driven molecular switch. These
two distinct conductance states were attributed to the electron tunneling
through the buckminsterfullerene anchoring group and fully extended
molecule 1, respectively. The assignment of conductance
features to these configurations was further confirmed by control
experiments with asymmetrically designed buckminsterfullerene derivative 2 as well as pristine buckminsterfullerene 3,
both lacking the GL feature.