Operating a Multi-Level Molecular Dimer Switch through Precise Tip-Molecule Control

Abstract

Controlling the state of molecules on surfaces is crucial for the advancement of molecular electronics. While reversible control of bistable molecule switches has been demonstrated, achieving controllable multi-state switching at the molecular scale remains a formidable challenge. In this study, we introduce a simple and effective strategy for the on-demand control of a multi-level molecular switch by creating a molecular dimer. We explore the transition behavior of a pyrrolidine dimer system on the Cu(100) surface using low-temperature scanning tunneling microscopy. By fine-tuning the voltage and tip-molecule distance, we can selectively determine the dominant state of the dimer system. Both intermolecular and tip-molecule interactions play a role in modifying the transition pathways, enabling precise multi-state control.