Design and Control of Highly Conductive Single-Molecule Junctions

This thesis describes improvements to and control of the electrical conductance in single-molecule junctions (SMJs), which have potential applications in molecular electronics, with a focus on the bonding between the metal and molecule. In order to improve the electrical conductance, the orbital of the molecule is directly bonded to the metal orbital, because anchoring groups, which were typically used in other studies to bind molecule with metal electrodes, became resistive spacers. Using this direct -binding, the author has successfully demonstrated highly conductive SMJs involving benzene, endohedral metallofullerene Ce@C82, and nitrogen. Subsequently, the author investigated control of the electrical conductance of SMJs using pyrazine. The nitrogen atom in the -conjugated system of pyrazine was expected to function as an anchoring point, and two bonding states were expected. One originates primarily from the orbital, while the other originates primarily from an n stateof the nitrogen. Measurements of conductance and dI/dV spectra coupled with theoretical calculations revealed that the pyrazine SMJ has bistable conductance states, in which the pyrazine axis is either tilted or parallel with respect to the junction axis. The bistable states were switched by changing the gap size between the metal electrodes using an external force. Notably, it is difficult to change the electrical properties of bulk-state materials using mechanical force. The findings reveal that the electron transport properties of a SMJ can be controlled by designing a proper metalmolecule interface, which has considerable potential for molecular electronics. Moreover, this thesis will serve as a guideline for every step of SMJ research: design, fabrication, evaluation, and control.

Nominated by Tokyo Institute of Technology as an outstanding Ph.D. thesis Provides technical information for each step of the research of single-molecule junctions: fabrication, evaluation, and control of electrical conductance Gives detailed insight regarding a highly conductive single-molecule electronic device Includes supplementary material: sn.pub/extras

Inhalt
Introduction.- Theoretical background.- Experimental concepts and techniques.- Design of the metalmolecule interaction at the benzene single-molecule junction.- Design of the interface structure of a single-molecule junction utilizing spherical endohedral Ce@C82 metallofullerenes.- Anchoring groups enclosed in the -conjugated system in N2 molecules.- Controlling the electrical property of highly conductive pyrazine single-molecule junction.- General conclusions.