Molecular Antennas and Photoactive Nanomaterials based on Energy Transfer Processes
- Iñigo López Arbeloa Director/a
- Jorge Bañuelos Prieto Director/a
Universidad de defensa: Universidad del País Vasco - Euskal Herriko Unibertsitatea
Fecha de defensa: 11 de diciembre de 2014
- Luis María Lezama Diago Presidente/a
- Hegoi Manzano Moro Secretario/a
- Inmaculada García-Moreno Gonzalo Vocal
- Boyko Yuda Koen Vocal
- Sylvie lacombe Vocal
Tipo: Tesis
Resumen
The scope of this thesis deals is the development and description of photoactive lnanomaterials and novel multichromophoric systems as artificial antenna systems. To this aim, the photophysical signatures of luminescent fluorophores (with absorption and emission at different regions of the visible electromagnetic spectrum) encapsulated into inorganic and organic hosts, or assembled in supramolecular structures have been exhaustively characterized. These systems are able to harvest the light over a broad spectral region (ultraviolet-visible) and transfer it to the target place and with a specific energy via successive energy transfer hops. As consequence the excitation can be performed far away from the emission region, improving the photostability of the acceptor emitting dye and a lowering the background interferences.In pursuit of such antennas, different alternatives have been considered, (i) Hybrid materials based on LTL zeolites doped with laser dyes working in the blue, green or red parts of the visible. (ii) Latex nanoparticles doped simultaneously with luminescent fluorophores, leading to stable aqueous colloids. (iii) Molecular cassettes based on energy donor and acceptor dyes covalently linked. All of them undergoing efficient and tunable energy transfer processes, the key factor for a successful development of luminescent antennas.In conclusion, the herein reported approaches (photoactive materials and novel dyes) towards the development of luminescent antennas are shown to be properly applied in photonic fields such as tunable dye lasers, light modulators or polarity probes