Pressure Response of Organic Photonic Materials at the Nano- and Mesoscale

Abstract

The synthesis and application of photonic materials have enjoyed much attention in recent years. However, many fundamental properties of such materials are still unexplored, especially for organic meso- and nanostructured materials. We propose to study the response of the optical and electronic properties of organic meso- and nanostructured materials to high pressure. The orbital overlap in organic materials is a very important factor for their optical and electronic properties. Pressure allows to tune intermolecular distances – and thus the orbital overlap – without changing the chemical composition of a material, and can be seen as an alternative to the more laborious approach of chemical modification. This provides the means to tune the photophysics, e.g., exciton states and exciton-phonon coupling in a material. In addition, solid-to-solid phase transitions between different polymorphs can make different morphologies accessible. In nano- and mesoscale materials, the necessary pressures of such phase transitions depend upon the size of the particles. We will prepare nano- and mesoscale crystals of polycyclic aromatic hydrocarbons (e.g., perylene, rubrene) and subject them to pressures up to 10 GPa in a diamond anvil cell. We will measure absorption, photoluminescence and (where possible) Raman spectra of these materials to determine phase transition pressures as a function of size and polymorph, obtain information on their electronic structure as a function of pressure, and characterize their pressure response as a function on crystallite size.