posted on 2018-07-02, 00:00authored byHong-Liang Lu, Yun Cao, Jing Qi, Anne Bakker, Cristian A. Strassert, Xiao Lin, Karl-Heinz Ernst, Shixuan Du, Harald Fuchs, Hong-Jun Gao
Molecular
rotors on solid surfaces are fundamental components of
molecular machines. No matter whether the rotation is activated by
heat, electric field or light, it is determined by the intrinsic rotational
potential landscape. Therefore, tuning the potential landscape is
of great importance for future applications of controlled molecular
rotors. Here, using scanning tunneling microscopy (STM), we demonstrate
that both tip–molecule distance and sample bias can modify
the rotational potential of molecular rotors. We achieve the potential
energy difference variations of ∼0.3 meV/pm and ∼18
meV/V between two configurations of a molecular rotor, a tetra-tert-butyl nickel phthalocyanine molecule on Au(111) substrate.
Further analysis indicates that the mechanism of modifying the rotational
potential is a combination of the van der Waals interaction and the
interaction between the molecular dipole and an electric field. This
work provides insight into the methods used to modify the effective
rotational potential energy of molecular rotors.