The molecular signature of highly conductive metal-molecule-metal junctions

TL;DR

This study investigates the conductance properties of six different molecules in platinum-based single-molecule junctions, revealing metallic conductance levels and molecular vibrational effects on conductance signatures.

Contribution

It provides detailed experimental data on conductance and vibrational effects in platinum-molecule junctions, advancing understanding of molecular electronics.

Findings

All molecules show conductance around 1G0 due to platinum contacts.

Molecular vibrations influence inelastic conductance contributions.

Molecular signatures are well-expressed despite metallic conductance.

Abstract

The simplicity of single-molecule junctions based on direct bonding of a small molecule between two metallic electrodes make them an ideal system for the study of fundamental questions related to molecular electronics. Here we study the conductance properties of six different molecules suspended between Pt electrodes. All the molecular junctions show a typical conductance of about 1G0 which is ascribed to the dominant role of the Pt contacts. However, despite the metallic-like conductivity, the individual molecular signature is well-expressed by the effect of molecular vibrations in the inelastic contribution to the conductance.