MSc Thesis Title: Catalytic hydrogenation of CO2 over supported Ni and Ru catalysts

Tuesday 30 October  2018, at:9:30, Venue: Hall Κ2.A3

Examination Committee

• Assistant Professor Paraskevi Panagiotopoulou (advisor)
• Professor Ioannis Yentekakis
• Assistant Professor Nikolaos Xekoukoulotakis

Abstract:

Carbon dioxide (CO₂) is one of the main greenhouse gases, which is responsible for global warming and therefore, considerable climate changes. Consequently, efforts have been made in order to develop efficient and environmental friendly technologies for CO₂ elimination and utilization. Catalytic hydrogenation of CO₂, which is one of the proposed utilization processes, is of great importance because it can create new ways for producing chemicals and fuels of high added value depending on the catalyst and reaction conditions employed. CO₂ methanation offers certain advantages provided that hydrogen is generated from renewable energy sources. Specifically, methane produced can be used as synthetic substitute of natural gas in chemical and petrochemical industry and/or as energy carrier in power plants following well established methods for its storage and transfer.

In the present study, the effect of the nature of the support on catalytic activity and selectivity of supported nickel (Ni) and ruthenium (Ru) catalysts for the CO₂ methanation reaction is investigated. In particular, the use of various metal oxides supports (Al₂O₃, CeO₂, ZrO₂, YSZ, TiO₂) and the potential to improve catalytic performance of Ru/TiO₂ and Ni/TiO₂ by addition of small amounts (0.2 wt.%) of promoters (Ce, Zr, La, Ca, Ba) on TiO₂ was studied. Furthermore, the use of bimetallic (Ni-Ru) catalysts supported on TiO₂ and the effect of operating parameters of the reaction on the activity and selectivity of 5%Ni/CeO₂ catalyst were investigated. Catalysts were synthesized employing the wet impregnation method and characterized with respect to their specific surface area and support crystallite size, employing nitrogen physisorption (BET) and X-ray diffraction (XRD), respectively. Catalytic performance was investigated in the temperature range 150-450 ^οC, using a feed stream consisting of 5%CO₂ +20%H₂ (in He).

Results showed that the nature of the support affects significantly the catalytic performance, which follows the order 5%Ni/CeO₂>5%Ni/ZrO₂>5%Ni/Al₂O₃~5%Ni/YSZ >5%Ni/TiO₂. Both activity and selectivity toward CH₄ of Ni catalysts do not seem to improve significantly by addition of promoters (0.2 wt. %) Νa and Zr on TiO₂ support. In contrast, the addition of (0.2 wt. %) Ce, Zr, La, Ca and Ba promoters on TiO₂ surface resulted in a significant increase of the activity of Ru catalysts, with the Ce-promoted sample (0.5%Ru/0.2%Ce-TiO₂) presenting the optimal performance. Thus, the effect of Ce loading on catalytic performance was investigated, which did not seem to present any trend with respect to catalytic activity. The use of bimetallic Ni-Ru/TiO₂ catalysts resulted in an increase of CO₂ conversion toward CH₄, which seemed to increase progressively with increasing Ru content from 0.25 to 1 wt.%. However, the monometallic catalyst 1%Ru/TiO₂ presented significantly higher activity compared to that obtained over the bimetallic catalysts.

Finally, the effect of operating parameters was investigated with respect to catalytic activity of 5%Ni/CeO₂ catalyst, and it was found that CO₂ conversion to CH₄ increases with decreasing space velocity and increasing Η₂/CO₂ molar ratio. Apart from high activity and selectivity, 5%Ni/CeO₂ catalyst, , presented exceptional stability for more than 30 hours on stream, indicating that it is a promising catalyst for CO₂ hydrogenation reaction.