Fuel from a Greenhouse Gas

One step toward carbon dioxide (CO₂) neutrality and the mitigation of both the greenhouse effect and the energy crisis would be to convert CO₂ into hydrocarbon-based fuels like methane using light. In the journal Angewandte Chemie, a Chinese research team has introduced a highly effective photocatalyst based on gold atoms to make this transformation possible.

The photocatalytic conversion of CO₂ occurs through a series of processes in which electrons are transferred. This can result in various products, including carbon monoxide (CO), methanol (CH₃OH), methane (CH₄), and other hydrocarbons. Eight electrons must be transferred on the way from CO₂ to CH₄— more than for other C₁ products. Methane is the thermodynamically favorable end product, but the competing reaction to form CO only requires two electrons and is much faster, so it is kinetically favored. Effective and selective methanization is thus particularly challenging.

A team led by Hefeng Cheng (Shandong University, Jinan, China) and co-workers has now developed a practical approach to efficiently convert CO₂ to CH₄ using solar energy. The key to their success is a novel catalyst with single gold atoms. Because gold atoms aggregate in conventional preparative methods, the team developed a new strategy that uses a complex exchange to produce the catalyst.

Because of their unique electronic structures, single-atom catalysts behave differently from conventional metal nanoparticles. Also, when fixed to a suitable support, nearly all single atoms are available as active catalytic centers. In this new catalyst, single gold atoms are anchored to an ultrathin zinc–indium sulfide nanolayer and are each coordinated to only two sulfur atoms. Under sunlight, the catalyst was demonstrated to be very active with a CH₄ selectivity of 77%.

A photosensitizer (a ruthenium complex) absorbs light, becomes excited, and accepts an electron that is made available by an electron donor (triethanolamine). It then passes the electron on to the catalyst. The single gold atoms on the surface of the support act as “electron pumps”. They capture the electrons significantly more effectively than gold nanoparticles and transfer them to CO₂ molecules and intermediates.

Detailed characterization and computations reveal that the catalyst activates the CO₂ molecules to a much greater degree than gold nanoparticles, more strongly adsorbs the excited *CO intermediates, lowers the energy barrier for binding hydrogen ions, and stabilizes the *CH₃ intermediate. This allows CH₄ to be the favored product and minimizes the release of CO.

About the Author

Dr. Hefeng Cheng is a Professor at the State Key Laboratory of Crystal Materials of Shandong University. His main research focus is defect chemistry engineering in semiconductor photocatalysis for solar energy harvesting and conversion, including water splitting, CO₂ reduction and so on.

Source:

Angewandte Chemie, press release, 2022-09-14.