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Thesis
Home   /   Thesis   /   Covalent 2D organic nanostructures by optically controlled cross-linking of molecular self-assemblies

Covalent 2D organic nanostructures by optically controlled cross-linking of molecular self-assemblies

Condensed matter physics, chemistry & nanosciences Radiation-matter interactions Solid state physics, surfaces and interfaces

Abstract

The self-assembly of molecules on crystalline substrates leads to non-covalent 2D structures with interesting properties for various fields such as optoelectronics and sensors. The stabilization of these 2D networks into covalent networks, while preserving these properties, is a major challenge and a topical issue. Various demonstrations show that crosslinking can be triggered by thermal processes. Photocrosslinking, on the other hand, is poorly described and the few examples that have been found involve ultra-high vacuum conditions.

Building on our previously developed know-how and the additional expertise of chemist collaborators, we therefore propose to carry out photocrosslinking of 2D networks at atmospheric pressure. We will use a model oligophenyl system that will be functionalized to allow photocrosslinking towards the production of a covalent 2D network. The resulting networks will be characterized through the correlation of optical spectroscopy and local probe microscopy to monitor and highlight photo-induced cross-linking processes at wavelength scale.

Laboratory

Institut rayonnement et matière de Saclay
Service de Physique de l’Etat Condensé
Laboratoire d’Electronique et nanoPhotonique Organique
Paris-Saclay
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