Sabatier-based CO₂-methanation by catalytic conversion

The catalytic conversion of CO₂ is an important component for the reintegration of secondary products like CO₂ or H₂ into the energy supply. An example is the “power to gas” concept with a conversion of CO₂ into CH₄. The CO₂ is transferred into a carrier of chemical energy, with the possibility to feed the produced CH₄ into the existing network of natural gas. At temperatures of around 350 °C, hydrogenation of CO₂ to CH₄ is possible by the Sabatier reaction CO₂ + 4H₂ → CH₄ + 2H₂O. One prerequisite for efficient kinetics of the Sabatier reaction is the application and optimization of catalysts. The focus of catalyst development is given to their performance under the conditions to be expected in the special application. As a part of the project Geoenergy-Research (GeoEn), we address questions related to the catalytic utilization of CO₂ produced in the course of the oxyfuel combustion of lignite. In this contribution, we report on the experimental setup in laboratory scale, which enables an advanced characterization of the catalytic performance, including thermodesorption measurements at atmospheric pressure in order to determine the amount of adsorbed CO₂ under real conditions. We also show data for activation energies, the catalytic performance as function of temperature and the long time stability of a commercial Ru-based catalyst.