Bond dissociation dynamics of single molecules on Ag(111)

TL;DR

This study uses low-temperature STM to investigate the bond dissociation dynamics of a single elongated molecule on Ag(111), revealing how substrate interactions influence bond breaking and molecular rotation, advancing understanding of surface chemistry.

Contribution

It demonstrates the dissociation and rotation behavior of a larger, elongated molecule on Ag(111) at the single-molecule level, highlighting substrate effects on bond dynamics.

Findings

Bond dissociation can propagate through the molecular backbone.

Fragment binds to the nearest silver atom after dissociation.

Substrate influences the dissociation and rotation processes.

Abstract

The breaking of a chemical bond is fundamental in most chemical reactions. To understand chemical processes in heterogeneous catalysis or on-surface polymerization the study of bond dissociation in molecules adsorbed on crystalline surfaces is advantageous. Single molecule studies of bond breaking can give details of the dissociation dynamics, which are challenging to obtain in mole-scale ensemble experiments. Bond breaking in single adsorbed molecules can be triggered using the energy of the tunnelling electrons in a scanning tunnelling microscope (STM) at selected positions to investigate the dissociation dynamics. Single bond dissociation dynamics has been deeply investigated only in small molecules, but not in larger molecules that exhibit distinct rotational degrees of freedom. Here, we use low temperature (7 K) STM to dissociate a single bromine atom from an elongated molecule (dibromo-terfluorene) adsorbed on a Ag(111) surface. This rod-like molecule allows to clearly identify not only displacement of the reaction fragments, but also their rotation. The results show that the molecular fragment binds to the nearest silver atom and only further rotation is allowed. Moreover, the excitation responsible for the bond breaking can propagate through the molecular backbone to dissociate a bromine atom that is not located at the pulse position. These results show the important role of the metal substrate in conditioning the bond dissociation dynamics. Our results might allow to improve the control of the synthesis of 2D materials and targeted engineering of molecular architectures.