Researchers develop a method for photo-mechanochemical synthesis of nanographenes in the solid-state

Professor Lars Borchardt’s team at Ruhr University Bochum, Germany, has succeeded in carrying out light-driven chemical reactions in the solid-state without resorting heavily to solvents. The team stated that this provides a sustainable alternative to established synthesis methods.

Light is considered the ideal driving force of chemical reactions as it’s cheap, available in abundance and produces no waste. This is why light-driven, i.e. photochemical reactions are highly attractive for the production of chemical compounds. However, they are usually carried out in huge amounts of solvents that are often toxic and generate hazardous waste in enormous quantities. Solid-state photochemical reactions without solvents could present an alternative. However, they have hardly been feasible so far, as they could only be mixed insufficiently and so it was possible to scale them up to relevant quantities.


For photochemical reactions to take place, photons must first reach the starting materials. In order for the reaction to be quick and complete, it’s essential for it to be thoroughly mixed. In conventional reactions, this is ensured by the solvent: it dissolves the substances, makes them mobile and increases mass transport and diffusion. So far, no equivalent method has been available in the solid-state.

The researchers in Bochum used ball mills as reactors. Here, the starting materials are placed in vessels together with milling balls and shaken at high frequencies. This creates high-energy impacts that provide the mechanical energy for the reaction and thoroughly mix the substances. In a photoreactor that was specially adapted to the mill, the researchers managed to carry out the ball milling process under irradiation. This facilitated photo-mechanochemical synthesis of nanographenes in the solid-state.

“This new process enabled us to carry out specific reactions and synthesize chemical substances in a much more sustainable way,” says Professor Lars Borchardt. “We reduced reaction times by up to 56 percent, while using 98 percent less solvent than in equivalent syntheses done with conventional methods. Last but not least, the new photoreactor consumes almost 80 per cent less energy than conventional equipment.”

Posted: Mar 16,2023 by Roni Peleg