Summary
While mature solar technologies (i.e. photovoltaics, photo-electrochemical cells) cannot simultaneously address the multi-faceted future energy challenge, PLANKT-ON aims to develop a disruptive net-zero emissions technology to both address the global energy demand and reoxygenation of our planet. Inspired by Nature, we propose to assemble the first synthetic plankton-like protocells that autonomously utilise light, water, and CO2 to produce O2 and formate, as a green H2 vector. To this aim, the plankton-like protocells will be shaped as containers of two synergic subdomains mimicking the natural plastids and the CO2-enzyme organelles. The artificial plastid (1st type proto-organelle) will utilise light to oxidise H2O to O2 and reduce a methyl viologen (MV) cofactor, this latter will feed the CO2-rich proto-organelle to selectively produce formate by a cascade enzymatic reaction. We are expecting that this original bio-inspired strategy will open a route to sustainable solar hydrogen.
The long term impact is envisaged for scientific innovation in groundbreaking solar-technology, going beyond the conventional photoelectrochemical cabled asset, and readily exploitable for empowering the EU vision for “Smart Buildings as Micro-Energy Hubs” in the world. Fundamental Research advances will be monitored by PLANKT-ON innovation radar activities, protected by our IP policy and disseminated to reach the expected stakeholders and the general public.
Multidisciplinary collaboration among the 6 partners, from 4 EU countries, 5 research centres, and 1 technology-based company, underpins the project activities that will target the EU mission. PLANKT-ON counts on the valuable experience of its Scientific Advisory Committee where international renowned scientists from Princeton (USA), Berkeley (USA), Tokyo (Japan) and EPFL-Lausanne (Switzerland) will contribute to the results evaluation and benchmarking in the field of light management, photo-catalysis and green H2 transport.
The long term impact is envisaged for scientific innovation in groundbreaking solar-technology, going beyond the conventional photoelectrochemical cabled asset, and readily exploitable for empowering the EU vision for “Smart Buildings as Micro-Energy Hubs” in the world. Fundamental Research advances will be monitored by PLANKT-ON innovation radar activities, protected by our IP policy and disseminated to reach the expected stakeholders and the general public.
Multidisciplinary collaboration among the 6 partners, from 4 EU countries, 5 research centres, and 1 technology-based company, underpins the project activities that will target the EU mission. PLANKT-ON counts on the valuable experience of its Scientific Advisory Committee where international renowned scientists from Princeton (USA), Berkeley (USA), Tokyo (Japan) and EPFL-Lausanne (Switzerland) will contribute to the results evaluation and benchmarking in the field of light management, photo-catalysis and green H2 transport.
Unfold all
/
Fold all
More information & hyperlinks
| Web resources: | https://cordis.europa.eu/project/id/101099192 |
| Start date: | 01-04-2023 |
| End date: | 31-03-2026 |
| Total budget - Public funding: | 2 533 216,25 Euro - 2 533 216,00 Euro |
Cordis data
Original description
While mature solar technologies (i.e. photovoltaics, photo-electrochemical cells) cannot simultaneously address the multi-faceted future energy challenge, PLANKT-ON aims to develop a disruptive net-zero emissions technology to both address the global energy demand and reoxygenation of our planet. Inspired by Nature, we propose to assemble the first synthetic plankton-like protocells that autonomously utilise light, water, and CO2 to produce O2 and formate, as a green H2 vector. To this aim, the plankton-like protocells will be shaped as containers of two synergic subdomains mimicking the natural plastids and the CO2-enzyme organelles. The artificial plastid (1st type proto-organelle) will utilise light to oxidise H2O to O2 and reduce a methyl viologen (MV) cofactor, this latter will feed the CO2-rich proto-organelle to selectively produce formate by a cascade enzymatic reaction. We are expecting that this original bio-inspired strategy will open a route to sustainable solar hydrogen.The long term impact is envisaged for scientific innovation in groundbreaking solar-technology, going beyond the conventional photoelectrochemical cabled asset, and readily exploitable for empowering the EU vision for “Smart Buildings as Micro-Energy Hubs” in the world. Fundamental Research advances will be monitored by PLANKT-ON innovation radar activities, protected by our IP policy and disseminated to reach the expected stakeholders and the general public.
Multidisciplinary collaboration among the 6 partners, from 4 EU countries, 5 research centres, and 1 technology-based company, underpins the project activities that will target the EU mission. PLANKT-ON counts on the valuable experience of its Scientific Advisory Committee where international renowned scientists from Princeton (USA), Berkeley (USA), Tokyo (Japan) and EPFL-Lausanne (Switzerland) will contribute to the results evaluation and benchmarking in the field of light management, photo-catalysis and green H2 transport.
Status
SIGNEDCall topic
HORIZON-EIC-2022-PATHFINDEROPEN-01-01Update Date
31-07-2023
Images
No images available.
Geographical location(s)
Search
Organisations
-
| CONSORZIO INTERUNIVERSITARIO NAZIONALE PER LA SCIENZA E TECNOLOGIA DEI MATERIALI (Coördinator)
-
| ASOCIACION CENTRO DE INVESTIGACION COOPERATIVA EN BIOMATERIALES- CIC biomaGUNE
-
| COMMISSARIAT A L ENERGIE ATOMIQUE ET AUX ENERGIES ALTERNATIVES (CEA)
-
| ENPHOS S.R.L.
-
| Politecnico di Milano
-
| UNIVERSITY OF BRISTOL (UOB)