Descripción del proyecto
Avanzar hacia aplicaciones energéticas más limpias
Los marcos organometálicos (MOM) son materiales cristalinos de gran porosidad que contienen matrices de iones metálicos cargados positivamente. Sus propiedades los hacen adecuados para fines catalíticos con el fin de generar energía limpia. El proyecto Supramol, financiado por el Consejo Europeo de Investigación, pretende mejorar el rendimiento catalítico de los MOM mediante modificaciones del tamaño, la forma y la carga. Los investigadores también incorporarán grupos funcionales y fotosensibilizadores para permitir la absorción de la luz, desencadenando eventos de transferencia de electrones y activando los centros catalíticos. El objetivo final es lograr una conversión eficiente de la luz en energía química, lo que supondría un importante avance científico de gran repercusión para las generaciones futuras.
Objetivo
Metal-organic frameworks (MOFs) are key compounds related to energy storage and conversion, as their unprecedented surface areas make them promising materials for gas storage and catalysis purposes. We believe that their modular construction principles allow the replication of key features of natural enzymes thus demonstrating how cavity size, shape, charge and functional group availability influence the performances in catalytic reactions. This proposal addresses the question of how such novel, bio-inspired metallo-supramolecular systems can be prepared and exploited for sustainable energy applications. A scientific breakthrough that demonstrates the efficient conversion of light into chemical energy would be one of the greatest scientific achievements with unprecedented impact to future generations. We focus on the following key aspects:
a) MOFs containing novel, catalytically active complexes with labile coordination sites will be synthesised using rigid organic ligands that allow us to control the topologies, cavity sizes and surface areas. We will incorporate photosensitizers to develop robust porous MOFs in which light-absorption initiates electron-transfer events that lead to the activation of a catalytic centre. In addition, photoactive molecules will serve as addressable ligands whereby reversible, photo-induced structural transformations impose changes to porosity and chemical attributes at the active sites.
b) Catalytic studies will focus on important oxidations of alkenes and alcohols. These reactions are relevant to H2-based energy concepts as the anodic liberation of protons and electrons can be coupled to their cathodic recombination to produce H2. The studies will provide proof-of-concept for the development of photocatalytic systems for the highly endergonic H2O oxidation reaction that will be explored using most stable MOFs. Further, gas storage and magnetic properties that may also be influenced by light-irradiation will be analysed.
Ámbito científico
Not validated
Not validated
- natural scienceschemical sciencesinorganic chemistryinorganic compounds
- natural scienceschemical scienceselectrochemistryelectrolysis
- natural scienceschemical sciencesorganic chemistryalcohols
- natural scienceschemical sciencescatalysis
- natural sciencesbiological sciencesbiochemistrybiomoleculesproteinsenzymes
Programa(s)
Régimen de financiación
ERC-COG - Consolidator GrantInstitución de acogida
D02 CX56 Dublin
Irlanda