Abstract: This thesis describes different ways of converting CO 2 to high value-added chemicals. For that, we tested traditional (γ-Al 2 O 3 , TiO 2 and MgO based catalysts) and non-traditional (MAX phase and MXene based catalysts) materials in different thermocatalytic reactions: butane dry reforming (where CO 2 reacts with butane to produce syngas), reverse water-gas shift (RWGS, where CO 2 reacts with H 2 to CO and H 2 O), and butane oxidative dehydrogenation (ODH) to produce butenes. In addition to thermal-catalysis, we used plasma-catalysis to perform CO 2 splitting and CO 2 hydrogenation to methanol. Overall, we found that Ti-based MAX phases are promising supports for CO 2 conversion reactions due to their stability, acidity and electronic properties. We have also shown that MXenes are promising catalysts in redox reactions due to their electronic properties and their ability to stabilise vacancy sites. Regarding plasma-enhanced catalysis, we have seen that metal oxide supported catalysts are able to improve CO 2 conversion and tune the selectivity in a DBD plasma setup, near ambient temperature and pressure. The metal loading and the metal oxide dispersion played important roles during CO 2 hydrogenation. Similar materials had no catalytic effect during CO 2 splitting in RF plasma. Nevertheless, we found that metal meshes can also act as catalysts under these conditions, increasing the CO yield.
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