Stabilizing a Molecular Switch at Solid Surfaces: A Density-Functional Theory Study of Azobenzene at Cu(111), Ag(111), and Au(111)

TL;DR

This study uses density-functional theory to analyze how azobenzene molecules bind and stabilize at copper, silver, and gold surfaces, revealing how surface interactions influence the molecule's conformational stability.

Contribution

It provides a detailed DFT analysis of azobenzene's conformational stability on coinage metal surfaces, highlighting the competition between covalent bonding and surface interactions.

Findings

Cis conformer is more stabilized at the surfaces due to geometric factors.

Binding strength varies across Cu(111), Ag(111), and Au(111), affecting isomer stability.

Surface interactions can reverse the gas-phase energetic order of azobenzene conformers.

Abstract

We present a density-functional theory trend study addressing the binding of the trans-cis conformational switch azobenzene (C6H5-N=N-C6H5) at three coinage metal surfaces. From the reported detailed energetic, geometric, and electronic structure data we conclude that the governing factor for the molecule-surface interaction is a competition between covalent bonding of the central azo (-N=N-) bridge on the one hand and the surface interaction of the two closed-shell phenyl (-C6H5) rings on the other. With respect to this factor the cis conformer exhibits a more favorable gas-phase geometric structure and is thus more stabilized at the studied surfaces. With the overall binding still rather weak the relative stability of the two isomers is thereby reduced at Ag(111) and Au(111). This is significantly different at Cu(111), where the cis bonding is strong enough to even reverse the gas-phase energetic order at the level of the employed semi-local electronic exchange and correlation (xc) functional. While this actual reversal may well be affected by the deficiencies due to the approximate xc treatment, we critically discuss that the rationalization of the general effect of the surface on the meta-stable molecular states is quite robust. This should equally hold for the presented analysis of recent tip-manipulation and photo-excitation isomerization experiments from the view point of the derived bonding mechanism.