# Electron transport through self-assembled monolayers of tripeptides

**Authors:** E. Mervinetsky, I. Alshanski, S. Lenfant, D. Guerin, L. Medrano, Sandonas, A. Dianat, R. Gutierrez, G. Cuniberti, M. Hurevich, S. Yitzchaik, and D. Vuillaume

arXiv: 1904.04887 · 2019-05-07

## TL;DR

This study investigates how copper ion complexation affects electron transport and work function in GGH peptide monolayers, revealing density-dependent conformational and electronic changes with implications for molecular electronics.

## Contribution

It demonstrates the density-dependent effects of Cu2+ complexation on electron transport and work function in peptide monolayers, supported by experimental and first-principles calculations.

## Key findings

- Copper complexation increases work functions systematically.
- Low-density monolayers show enhanced electron transport upon Cu2+ binding.
- High-density monolayers become more insulating after copper complexation.

## Abstract

We report how the electron transport through a solid-state metal/Gly-Gly-His tripeptide (GGH) monolayer/metal junction and the metal/GGH work function are modified by the GGH complexation with Cu2+ ions. Conducting AFM is used to measure the current-voltage histograms. The work function is characterized by combining macroscopic Kelvin probe and Kelvin probe force microscopy at the nanoscale. We observe that the Cu2+ ions complexation with the GGH monolayer is highly dependent on the molecular surface density and results in opposite trends. In the case of a high density monolayer the conformational changes are hindered by the proximity of the neighboring peptides, hence forming an insulating layer in response to copper-complexation. Whereas the slightly lower density monolayers allow for the conformational change to a looped peptide wrapping the Cu-ion, which results in a more conductive monolayer. Copper-ion complexation to the high- and low-density monolayers systematically induces an increase of the work functions. Copper-ion complexation to the low-density monolayer induces an increase of electron transport efficiency, while the copper-ion complexation to the high-density monolayer results in a slight decrease of electron transport. Both of the observed trends are in agreement with first-principle calculations. Complexed copper to low density GGH-monolayer induces a new gap state slightly above the Au Fermi energy that is absent in the high density monolayer.

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Source: https://tomesphere.com/paper/1904.04887