Objectif Nature has been harnessing solar energy to drive endergonic life-sustaining reactions such as photosynthesis for billions of years. However, the overall biological processes are inefficient despite the evolution of efficient enzymes for carrying out specific reactions. Currently, there is an urgent need to develop superior strategies for the large scale conversion of solar energy into a renewable chemical fuel through artificial photosynthesis, which uses the same fundamental science as natural photosynthesis. Here we integrate the strengths of both natural and artificial photosynthesis to explore novel pathways for efficient solar-to-chemical conversion, which are otherwise inaccessible to either field alone.In aim 1, we develop advanced materials and strategies for the rational integration of photosynthetic enzymes into photoelectrochemical cells. A platform will be established in which enzymes can be artificially coupled to light absorbers, and also be wired together to perform novel chemical reactions.In aim 2, we adapt advanced analytical techniques, including scanning electrochemical microscopy and time-resolved spectroscopy, to gain mechanistic insights into the nature, extent, and mechanism of the enzyme-material interaction. This will aid rational cell design and shed light into reaction bottlenecks.In aim 3, we wire the enzyme-electrodes together in rational combinations to arrive at novel and efficient pathways for performing solar-to-fuel conversions. We will demonstrate the efficient coupling of solar energy harvesting with water oxidation and proton/carbon dioxide reduction.This integrated approach will lead the emergent field of semi-artificial photosynthesis beyond conventional solar fuels research. It will probe into the strengths and weaknesses of biological processes, and be used to explore how other processes (e.g. nitrogen fixation, C–H bond activation) can be more efficiently re-wired or be coupled to photochemistry. Champ scientifique engineering and technologyenvironmental engineeringenergy and fuelsrenewable energysolar energyengineering and technologyindustrial biotechnologybioprocessing technologiesengineering and technologyenvironmental engineeringenergy and fuels Mots‑clés MatEnSAP Programme(s) H2020-EU.1.1. - EXCELLENT SCIENCE - European Research Council (ERC) Main Programme Thème(s) ERC-CoG-2015 - ERC Consolidator Grant Appel à propositions ERC-2015-CoG Voir d’autres projets de cet appel Régime de financement ERC-COG - Consolidator Grant Institution d’accueil THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE Contribution nette de l'UE € 1 960 289,00 Adresse TRINITY LANE THE OLD SCHOOLS CB2 1TN Cambridge Royaume-Uni Voir sur la carte Région East of England East Anglia Cambridgeshire CC Type d’activité Higher or Secondary Education Establishments Liens Contacter l’organisation Opens in new window Site web Opens in new window Participation aux programmes de R&I de l'UE Opens in new window Réseau de collaboration HORIZON Opens in new window Coût total € 1 960 289,00 Bénéficiaires (1) Trier par ordre alphabétique Trier par contribution nette de l'UE Tout développer Tout réduire THE CHANCELLOR MASTERS AND SCHOLARS OF THE UNIVERSITY OF CAMBRIDGE Royaume-Uni Contribution nette de l'UE € 1 960 289,00 Adresse TRINITY LANE THE OLD SCHOOLS CB2 1TN Cambridge Voir sur la carte Région East of England East Anglia Cambridgeshire CC Type d’activité Higher or Secondary Education Establishments Liens Contacter l’organisation Opens in new window Site web Opens in new window Participation aux programmes de R&I de l'UE Opens in new window Réseau de collaboration HORIZON Opens in new window Coût total € 1 960 289,00