Departmental Oral Examination (Thesis Title: "On-surface self-assembly and characterization of a macromolecular charge transfer complex by scanning tunneling microscopy and spectroscopy")

Event Date and Time: 
Fri, 2016-02-19 16:00 - 18:00
Henn 318
Local Contact: 
Physics and Astronomy, UBC
Intended Audience: 


In this thesis work, the morphology and electronic structure of  thermally-activated, self-assembled linear nanochains, featuring a triiron linkage between two bisterpyridine-based ligands on an Ag(111) surface, have been investigated with scanning tunneling microscopy and spectroscopy. An in situ, clean and reliable on-surface preparation technique was developed for self-assembly of complexes based on the metal-organic motif of dyes successfully used in photovoltaic and catalysis applications. Tunneling spectroscopy on the metal-organic nanostructures obtained suggests the formation of a coordination bond with charge transfer from metal to ligand. Further, the electronic structure indicates the presence of the desired metal-to-ligand charge transfer optical transition, characteristic of the related complexes. The unprecedented triiron coordination link has potential for being an efficient reaction center for catalysis applications, as well as for having interesting magneto, spin, and electronic properties. Each step and aspect of the chains formation process - from the bare ligands, to the coordination of bare terpyridine groups with single iron atoms, and the nucleation and growth of longer chains - have been characterized from scanning tunneling microscopy measurements and growth studies, and the results are supported by density functional theory calculations. Additionally, the relevance and influence of the silver metal substrate on both bare ligands and chains have been investigated. Bare molecules show a strong interaction with the substrate, as demonstrated by their specific adsorption configurations and an electronic structure, which is different then from when they are electronically decoupled from the surface. Conversely, when the molecules are in chains the silver plays a key role in the structure of the coordination link.

This work shows the potential of using on-surface self-assembly and scanning tunneling microscopy and spectroscopy, not only to prepare with high-fidelity clean and controlled structures but also as a flexible platform to investigate and tailor functional properties of different systems for a large variety of applications where a solid support is essential.

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