{"id":1020,"date":"2025-09-17T10:39:12","date_gmt":"2025-09-17T08:39:12","guid":{"rendered":"https:\/\/w-platform.fr\/?p=1020"},"modified":"2025-09-18T09:28:43","modified_gmt":"2025-09-18T07:28:43","slug":"transformer-le-co%e2%82%82-en-molecules-dinteret-et-produire-de-loxygene-pour-loxy-combustion","status":"publish","type":"post","link":"https:\/\/w-platform.fr\/en\/2025\/09\/17\/transformer-le-co%e2%82%82-en-molecules-dinteret-et-produire-de-loxygene-pour-loxy-combustion\/","title":{"rendered":"Transform CO\u2082 into molecules of interest and produce oxygen for oxy-fuel combustion."},"content":{"rendered":"

Oxy-combustion is a technology that involves burning a fuel in the presence of pure oxygen, rather than using ambient air. This produces fumes containing mainly CO\u2082 and water vapor, making it easier to capture CO\u2082 for storage or recovery. However, the production of pure oxygen is energy-intensive. An alternative is to develop processes capable of converting CO\u2082 into molecules of interest while producing pure oxygen as a co-product. <\/p>\n\n\n\n

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  1. Biological systems: natural photosynthesis<\/strong><\/li>\n<\/ol>\n\n\n\n

    Plants, algae and cyanobacteria fix CO\u2082 with light, producing organic molecules such as sugars, lipids and organic acids. Oxygen is released when water is oxidized in the photobioreactor.<\/p>\n\n\n\n

    Benefits<\/strong> A natural, direct process using low-consumption solar or artificial energy. 
    Limits<\/strong> low photosynthetic yield (< 5 %), high surface and resource requirements. <\/p>\n\n\n\n

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    1. Artificial systems inspired by photosynthesis: a) Artificial photosynthesis : <\/strong>This approach is inspired by natural photosynthesis, but with improved efficiency. Research carried out by the CNRS has shown that photocatalysis can be a promising route for CO\u2082 conversion, particularly when combined with advanced catalytic materials. CNRS Le journal<\/a>  b) Electrolysis of CO\u2082 : <\/strong>CO\u2082 electrolysis is an electrochemical process in which CO\u2082 is reduced at the cathode to produce fuels or chemicals, while at the anode, water is oxidized to produce pure oxygen. This process offers flexibility in the products obtained and can be coupled with renewable energy sources. According to IFP Energies Nouvelles, CO\u2082 electrolysis is a developing technology with significant potential for CO\u2082 recovery, although challenges remain in terms of cost and efficiency. ifpenergiesnouvelles.fr<\/a><\/li>\n\n\n\n
    2. Thermochemical metal oxide cycles<\/strong>Thermochemical cycles use metal oxides, such as cerium (CeO\u2082), to carry out reduction and oxidation reactions. At high temperatures, the metal oxide is reduced, releasing pure oxygen. This reduced material is then reoxidized by CO\u2082, producing CO and regenerating the metal oxide. A thesis from the University of Perpignan investigated the use of thermochemical cycles for the production of synthetic solar fuels, highlighting their potential for CO\u2082 upgrading. theses.fr<\/a><\/li>\n\n\n\n
    3. Hybrid approaches<\/strong>Combined solutions are emerging to improve the efficiency of CO\u2082 conversion: