SUnlight-driven Next Generation Artificial photosynthesis bio-hybrid TEchnology platform for highly efficient carbon neutral production of solar fuels

Climate, Energy & MobilityHORIZON-RIAID: 101122061
EC Contribution
€48,970
Consortium Size
10 orgs
Start Year
2023
Summary

Artificial photosynthesis (AP) is a promising approach for solar fuel production, but current systems are inefficient, expensive and unsuitable for industrial deployment. The interdisciplinary SUNGATE consortium of 12 partners from six EU countries and Turkey will overcome these limitations by combining the principles of AP with photoelectrocatalysis and flow microreactor technology, leading to the first modular full-cell continuous flow microreactor technology that requires only sunlight (as an energy source) plus water and CO2 (as simple, abundant feedstocks) for conversion into solar fuels such as methanol and formate. The technology will operate at room temperature and neutral pH using aqueous solutions. In contrast to state-of-the-art photoelectrochemical (PEC) technologies, SUNGATE will not use toxic or critical raw materials, and will combine efficient water oxidation catalysts, with biological components such as photosystem I and enzymes, novel CO2 reducing catalysts and nanostructured diamond-based cathodes to radically improve the efficiency of conversion. The unique modular and scalable design of SUNGATE technology will allow the decarbonised production of solar fuels by increasing the size of the microfluidic PEC device or by numbering up the PEC modules, thus providing the flexibility for diverse applications ranging from decentralised energy infrastructure to closed carbon cycles for industries that emit large amounts of CO2. SUNGATE aims to achieve proof of concept at TRL5, heralding a technology breakthrough that has the potential to secure the future global energy supply at an affordable cost. This meets the central goal of the European Green Deal and the European Climate Law to achieve climate neutrality by 2050. SUNGATE’s diverse mix of academic, RTOs and industry partners will allow the full validation of the technology, including life cycle assessment, as well as effective dissemination and knowledge transfer to accelerate industrial take up.

Consortium (10)

Project Results (4)

Source: CORDIS, the EU research results database.

Publications (3)
Diamond Chemistry: Advances and Perspectives
Angewandte Chemie International Edition· 2025DOI
Nianjun Yang, Anke Krueger, Robert J. Hamers
Structural Influence on Exciton Formation and the Critical Role of Dark Excitons in Polymeric Carbon Nitrides
Advanced Energy Materials· 2025DOI
Changbin Im, Radim Beranek, Timo Jacob
Unraveling the optical signatures of polymeric carbon nitrides: insights into stacking-induced excitonic transitions
Journal of Materials Chemistry C· 2025DOI
Changbin Im, Mohamed M. Elnagar, Björn Kirchhoff, Dariusz Mitoraj, Igor Krivtsov, Attila Farkas, Radim Beranek, Timo Jacob
Other Results (1)
Periodic Reporting for period 1 - SUNGATE (SUnlight-driven Next Generation Artificial photosynthesis bio-hybrid TEchnology platform for highly efficient carbon neutral production of solar fuels)