Capturing carbon dioxide from the atmosphere and storing it in recycled concrete aggregate or geological reservoirs in Iceland is technically feasible and also has a positive carbon footprint, a new study shows.
Switzerland has set itself an ambitious goal: to reduce the country’s greenhouse gas emissions to net zero by 2050. But this will require more than just a massive expansion of renewable energies and saving measures.
The federal government assumes that hard-to-abate CO2 emissions, e.g. from incineration plants, will amount to 12 million tonnes (about 13.2 million tons) a year. Some of the CO2 emitted therefore needs to be removed again from the atmosphere. The question is, how? And what should be done with it?
Researchers investigated these questions as part of a pilot project and explored two solutions for permanent storage of CO2:
- Mineralization in recycled demolition concrete manufactured in Switzerland and
- Mineralization in a geological reservoir in Iceland.
The project used carbon dioxide emissions from a waste water treatment plant in Bern. The researchers performed a life cycle analysis that covered the entire chain—from the capture and liquefaction of CO2 at the point of origin, to its transport and permanent storage. They also calculated how much new CO2 is produced along the entire chain. In addition, they explored different solutions for carbon capture methods and technologies for a waste incineration plant and a cement manufacturing plant.
The project demonstrated that both pathways are technically feasible and have a positive climate impact. In all the examples examined, the amount of CO2 stored exceeded the emissions produced along the transport chain.
When storing in recycled demolition concrete, the efficiency and thus the ratio between stored emissions and resulting new emissions is 90%; when transporting Swiss CO2 and then storing it in a geological reservoir in Iceland, it’s around 80%.
This efficiency should improve in future as most of the new emissions arise from transporting the containers by rail and ship, and some of these modes of transport still use energy from coal-fired power stations as well as fossil fuels. If in future CO2 is to be exported on a large scale, constructing a pipeline would be a potential solution.
One aspect that did surprise researchers, on the other hand, was the regulatory difficulties encountered when trying to transport CO2 through several countries to Iceland. This was the first instance of cross-border carbon dioxide transport for storage.
“A lot of CO2 is needed in the food production industry, and can be transported across borders without any problem, labelled as chemicals. But if the carbon dioxide is in the form of waste—as in our case—the regulatory environment is very unclear,” says Marco Mazzotti, project coordinator and a professor at ETH Zurich.
The project team therefore came to the conclusion if Switzerland wants to store CO2 on a large scale and create incentives for companies in future, it needs to work with its European neighbors to agree on clear regulations.
Even though the technologies trialed in the project function correctly, much research is still needed in the area of CO2 management. It is also vital to make sure the technologies are worked up to a commercial scale.
In 2023 ETH Zurich researchers and partners in politics, science, and industry, set up the Coalition for Green Energy and Storage, one of whose aims is to accelerate the adoption and roll-out on an industrial scale of existing technologies for capturing CO2, producing carbon-neutral gases and fossil fuels, and permanently storing CO2.
Another question researchers are addressing is whether CO2 can also be stored underground closer to home, in Switzerland. A possible injection test in a borehole in Trüllikon no longer required by the National Cooperative for the Disposal of Radioactive Waste (NAGRA) could provide some initial answers.
Source: ETH Zurich
