Very encouraging results in terms of performance have also been obtained, whether for methanation or gas reforming on ceria-based materials and zeolites promoted ones. These results make it possible to confidently envisage the emergence of viable CO2 recycling technologies at the end of the project, providing an essential brick to meet the gigantic challenges of global warming.
PIONEER is also a place for the transmission of knowledge, obviously for the training of ESRs, but also for the scientific community and the general public. Tools such as a database of plasma/catalysis coupling performance is being built, as well as a standardised reactor to improve the relevance of comparisons of work carried out in various laboratories even beyond PIONEER consortium itself. A website and regular communications on Twitter, Instagram, and LinkedIn allow a wide dissemination of PIONEER's activities. In addition, the results are shared with the scientific community by taking part in conferences and publications.The Pioneer project is well launched and to date the expected results are encouraging, the ESRs are being followed the hoped-for trainings and the research is ongoing. As reported 3 WP are linked with results and potential impacts. The WP2 Fundamentals & Mechanisms addresses fundamental knowledge of the interaction between plasma and catalyst. This knowledge are crucial to know the constraints of the design of catalyst appropriate for CO2 plasmolysis. The WP 3 was dedicated to Advanced Catalysts for CO2 conversion under plasma exposure.
New catalysts were proposed and tested in BDB plasma for methane and methanol production, a coupling with modeling was also performed. Also, ultra pulsed plasma was used for methane reforming leading to syngas production. Finally the WP4 deled with Innovative routes for plasma/catalyst coupling. Here, the project has light on the transient conditions present both in-pulse as well as intra-pulse, where it has been shown that by tailoring the power pulsing scheme a highly perturbed environment is created that is conductive to CO2 dissociation, significantly reducing energy input, whereas it was shown also that Optimizing air plasma reactor requires detailed understanding of the reactor temperature and the impact pressure has upon the plasma parameters. In addition, it was shown that Investigating methods to vibrationally excite CO2 with plasma has the potential to facilitate the development of more sophisticated plasma chemistry models as it provides the fundamental cross section data as well as experimental data to validate the simulations. The Plasma-catalytic CO2 conversion in liquid water was studied for the first time in this project. The results show a significant change in paradigm in the field, since water is usually regarded as detrimental to the reactions of interest but it proved to be an interesting pathway to long-chain organic liquids, when used in liquid-phase. Furthermore, it was also observed that, to some extent, MnO was converted into MnCO3, and the conversion of oxides into carbonates is also a suitable strategy to fixate CO2, but still rather unexplored using plasma. Finally, the work developed in Pioneer carried out by complements fundamental studies in only CO2 and CO2-CH4 plasmas interacting with catalytic materials.