Scientists from the UK, Germany and Australia have successfully converted carbon dioxide (CO2) into methanol, a green fuel, using a new technique that they have developed.

The research involved chemists from the University of Birmingham, the University of Ulm and the University of Queensland, and was led by scientists at the School of Chemistry at the University of Nottingham.

The new approach does not require the use of hydrogen, as is the case with existing methods of converting CO2 into useful products. It employs a technology called photocatalysis, in which light is shone on a semiconductor material, thus exciting electrons and allowing them to move through the material and react with CO2 and water. This produces a range of useful products, including methanol. Hitherto, this process has suffered from inefficiency and inadequate selectivity.

The research team has successfully developed a new material, composed of individual copper atoms anchored to, or nested within, nanocrystalline carbon nitrate structures. This allows electrons to move from the carbon nitrate to the CO2. This is essential to allow the production of methanol from CO2, using sunlight to trigger the reaction.

“There is a large variety of different materials used in photocatalysis,” explained University of Nottingham School of Chemistry research fellow Dr Madasamy Thangamuthu. “It is important that the photocatalyst absorbs light and separates charge carriers with high efficiency. “In our approach, we control the material at the nanoscale. We developed a new form of carbon nitride with crystalline nanoscale domains that allow efficient interaction with light as well as sufficient charge separation.”

“We measured the current generated by light and used it as a criterion to judge the quality of the catalyst,” reported School of Chemistry PhD student Tara LeMercier. “Even without copper, the new form of carbon nitride is 44 times more active than traditional carbon nitride. “However, to our surprise, the addition of only 1 mg of copper per 1 g of carbon nitride quadrupled this efficiency. “Most importantly the selectivity changed from methane, another greenhouse gas, to methanol, a valuable green fuel.”

“It is vitally important to ensure the sustainability of our catalyst materials for this important reaction,” highlighted the School of Chemistry’s Professor Andrei Khlobystov. “A big advantage of the new catalyst is that it consists of sustainable elements – carbon, nitrogen and copper – all highly abundant on our planet.”

This research has opened the way for the development of extremely selective and tuneable catalysts, which would allow the ‘dialling up’ of the desired product, through control of the catalyst at the nanoscale.

The research has been funded by the UK’s Engineering and Physical Sciences Research Council, under its ‘Metal Atoms on Surfaces and Interfaces for a Sustainable Future’ (MASI) programme. MASI is focused on the development of catalyst materials to convert CO2, hydrogen and ammonia molecules, which are critically important in both economic and environmental terms, while ensuring the sustainable use of the chemical elements that make up the catalysts.