SBIR-STTR Award

Solar fuels production is necessary for the future of the global economy New highly conductive and stable polymer-electrolytes with low light absorption are required for efficient and cost- effective solar fuels generation Opus 12 will work with Prof Chulsung Bae at Rensselaer Polytechnic Institute (RPI) to further develop the existing polymer-electrolyte chemistry to meet the demands of this challenging application New materials will be synthesized at RPI and sent to Opus 12 where key performance metrics such as conductivity, gas crossover, and mechanical stability will be characterized Polymer-electrolytes will then be tested in Opus 12’s CO2 electrolyzer Results of characterization and performance tests will provide feedback to RPI to guide development Hitting our Phase I targets would allow us to scale up the polymer-electrolytes production in Phase II for use in commercial solar fuels development Utilizing low-cost and abundant solar energy to covert CO2 to fuel and value-added chemicals could positively impact the global carbon balance, reduce air pollution, and create new jobs in regions with few opportunities by distributing production of these materials

Using renewable electricity to power the electrochemical reduction of waste CO2 could form the basis of a sustainable carbon cycle to make solar fuels. Lack of highly conductive ionomers and polymer electrolyte membranes with superior mechanical robustness and permeation limit the application of solar fuels technology. This project’s goal is to develop a new type of visible light transparent polymer with the aromatic backbone structure with high performance and good durability for CO2 electroreduction. A series of crosslinked polymer electrolyte membranes will be fabricated in order to suppress the CO2 plasticization, swelling behavior, gas crossover, and improve mechanical durability. The new ionomers and membranes will then be tested in a CO2 electrolyzer. Results of characterization and performance tests will provide feedback and guide development in large scale production. The novel integration of aromatic backbone polymer and crosslinker will provide a viable solution to fabricate a large area polymer electrolyte membrane and ensure durable performance in solar fuel production. Utilizing low-cost and abundant solar energy to covert CO2 to fuel and value-added chemicals could positively impact the global carbon balance, reduce air pollution, and create new jobs in regions with few opportunities by distributing production of these materials.