Germany is progressing toward climate neutrality – and has to close carbon cycles in its industries as soon as possible to get there. To reach the 1.5-degree target, the Intergovernmental Panel on Climate Change (IPCC) suggests removing and permanently storing already emitted CO2. “We must find completely new technological solutions if we want to keep up industrial production,” says Dr Benjamin Dietrich of the KIT Institute of Thermal Process Engineering (TVT). ”This includes the industrial carbon supply. Carbon is needed to produce batteries, building materials, colours, and in the agricultural sector. So far, it comes largely from fossil sources.” In the research project NECOC (short for: NEgative CarbOn Dioxide to Carbon) coordinated by Dietrich, the associated partners KIT, INERATEC, and Climeworks developed a process to convert CO2 from the atmosphere into carbon. “If this carbon remains permanently bound, we successfully combine negative emission with a component of the post-fossil resource supply as part of a future carbon management strategy. This represents a double contribution to a sustainable future,” Dietrich explains. In the first project phase, the research team constructed a container-sized test facility, which now went into operation. This first-phase installation removes two kilograms of CO2 from the ambient air in one day and turns it into 0.5 kilograms of solid carbon.
In three steps from greenhouse gas to useful resource
The NECOC process combines three steps: The first is an absorber to separate the CO2 from the ambient air (Direct Air Capture). In the second step, the CO2 is moved to a microstructured reactor, which reacts with sustainably produced hydrogen from a connected electrolyzer. Its components, carbon and oxygen, form new bonds, and the CO2 becomes methane and water. While the water flows back to the electrolyzer, the methane, including the carbon, ends up in a reactor with liquid tin. This is where the third process step occurs: In rising bubbles, a pyrolysis reaction splits the methane molecules, creating hydrogen, which can be returned to split CO2. The remaining part is carbon, which floats on the tin as a micro granular that can be taken off mechanically on a regular basis. Changing process parameters like the temperature level allows the production of different carbon modifications like graphite, carbon black, or even graphene.
Optimize and scale for industrial application
The start of the test installation is an important milestone for the NECOC project, as well as the end of the first funding phase. In a second project phase, the NECOC procedure will now be scaled up and optimized for expansion. “We are planning to make the procedure more energy-efficient by improving the energy recovery from the process heat,” states project director Dr. Leonid Stoppel from the Karlsruhe Liquid Metal Laboratory (KALLA). “We are also looking into an integration of high-temperature heat storages and direct solar heating.” Additional points of research are the inclusion of CO2 point sources, novel approaches to the extraction of CO2 from the air, and the influence of trace components and impurities in the process network on the carbon quality.
Source: Karlsruher Institut für Technologie (KIT)