Researchers from the Queensland University of Technology have made a remarkable breakthrough with the development of an electrochemical process in which carbon dioxide is captured from the air and stored in water as a non-toxic calcium carbonate (chalk) in a renewably powered process that could also produce green hydrogen and decarbonize the cement industry. 

PhD researcher Olawale Oloye and Professor Anthony O’Mullane from the QUT Centre for Clean Energy Technologies and Practices developed the process of capturing and converting carbon dioxide through a mineralization approach that seems to produce a host of serendipitous by-products. 

According to O’Mullane, the “process involves the capture of CO2 by its reaction with an alkaline solution produced on demand, to form solid carbonate products which can be used, for example, as construction materials, thereby keeping carbon dioxide out of the atmosphere. This can be done using a simple calcium source in water.”

It is also important to note that the QUT researchers used seawater instead of potable water, as potable water is too precious a resource for large-scale carbon capture, especially in Australia.

“We found we could use seawater once it had been treated to remove sulphates. To do this we first precipitated calcium sulphate or gypsum, another building material, and then carried out the same process to successfully turn CO2 into calcium carbonate, thus providing proof of concept of a circular carbon economy,” O’Mullane said. “Next, the hydrogen evolution reaction during electrolysis ensured that the electrode was continually renewed to keep the electrochemical reaction going while also generating another valuable product, green hydrogen. This means if this electrolysis process is powered by renewable electricity, we are producing green hydrogen alongside the calcium carbonate (CaCO3).” 

The process captures and stores carbon dioxide from the atmosphere, while also generating a green fuel source capable of decarbonizing pesky industrial sectors such as heavy transport, manufacturing, and the entire energy sector of export partners like Japan. 

O’Mullane said the use of renewable energy to capture CO2 and create calcium carbonate may be needed in the cement industry, which is one of the tougher industries to decarbonize.

“We envision this technology would benefit emission-intensive industries such as the cement industry whose CO2 footprint is 7-10% of anthropogenic CO2 emissions,” said O’Mullane. “By coupling the mineralization process to produce CaCO3 from the emitted CO2 during the clinking step we could create a closed loop system and reduce a significant percentage of the CO2 involved in cement production.”

The scientists described their findings in “Electrochemical Capture and Storage of CO2 as Calcium Carbonate,” which was recently published in ChemSusChem.

By Blake Matich

Source PV Magazine

Related news

Decade of the plant and the continued evolution of food

With the ‘decade of the plant’ well underway, we take a look at how businesses can capitalise with an ERP system that understands food!

Big data, low carbon: how data centres innovate for sustainability

As digital demand grows, data centres are finding ways to reduce energy consumption at all levels of operation, from offering liquid cooling solutions to providing on-site prime power through fuel cells.

Regrowing Vegetables with Sun and Water

You may have seen that some vegetables have their roots attached, particularly leeks, green onions, and fennel. Instead of scrapping the roots, you can actually regrow the entire vegetable. All you need is a jar of water and a ledge in the sun, and you’ve got yourself a kitchen garden. You can do it all before the official garden season starts.

London-Auckland in zero emissions hydrogen-powered jet? UK-backed concept design unveiled

A UK-backed research group unveiled a design for a liquid hydrogen-powered airliner theoretically capable of matching the performance of current midsize aircraft without producing carbon emissions.