Interaction between fullerene-wheeled nanocar and gold substrate: A DFT study

Since the successful synthesis of nanocar and its surprising movement on the gold surface, several theoretical investigations have been devoted to explain the interaction properties as well as its movement mechanism on the substrate. All of them failed, however, to gain a clear theoretical insight into the respected challenges because of the weak computational methods implemented for this complex system including heavy metal atoms and giant size of the whole system. In this work, we have investigated the adsorption of fullerene-wheeled nanocar onto a Au (1 1 1) substrate using the comprehensive first principles density functional theory (DFT) simulations. The binding energy between the nanocar and Au (1 1 1) surface was determined to be -9.43 eV (-217.45 kcal/mol). The net charge transfer from the nanocar to the gold substrate was calculated to be about 9.56 electrons. Furthermore, the equilibrium distances between the Au surface and the C-60 molecule and nanocar chassis were estimated to be 2.20 angstrom and 2.30 angstrom, respectively. The BSSE correction was also considered in the binding energy estimation and the result show that the BSSE correction significantly affects the calculated binding energy for such systems. Finally, we have performed ab initio molecular dynamics simulation for a single C-60 fullerene on the gold surface at room temperature. Our first-principles result shows that ambient condition affect remarkably on the adsorption property of fullerene on the gold surface. We also observed that the C-60 fullerene wheel slips by approximately 3.90 angstrom within 5 ps of simulation time at 300 K. (C) 2016 Elsevier B.V. All rights reserved.