In the realm of co-electrolysis, H2Electro’s SOECs demonstrate remarkable versatility and efficiency. By performing co-electrolysis of water and carbon dioxide, these innovative cells enable the production of syngas, a valuable precursor for various chemical and fuel synthesis processes. The syngas produced can be utilized in Fischer-Tropsch processes to manufacture chemicals and hydrocarbon fuels, contributing to a diverse range of industrial applications.
One of the key advantages of H2Electro’s SOECs is their high operating temperature, which significantly enhances energy efficiency compared to other electrolysis technologies. Additionally, the incorporation of novel fully ceramic electrodes ensures resistance to carbon and sulfur contaminants, mitigating degradation issues and prolonging operational lifespan. This resilience translates into a more reliable and cost-effective co-electrolysis process, offering a sustainable alternative to traditional methods of syngas production.
Overall, H2Electro’s SOEC technology presents a transformative solution for both ammonia production and co-electrolysis applications. By leveraging renewable energy sources, optimizing energy conversion efficiency, and minimizing environmental impact, H2Electro is paving the way for a greener, more sustainable future in these vital sectors.

• H2Electro’s SOECs can perform co-electrolysis of water and carbon dioxide, offering versatility in syngas production.
• Syngas produced can be used for Fischer-Tropsch processes to make valuable chemicals and hydrocarbon fuels.
• H2Electro’s SOECs’ high operating temperature enhances energy efficiency.
• Novel fully ceramic electrodes in H2Electro’s SOECs resist carbon and sulfur contaminants, reducing degradation issues.
• Co-electrolysis with H2Electro’s SOECs offers a more efficient and cost-effective way to produce syngas compared to traditional methods.