News Release

Chemists develop new method for water splitting

Photocatalytic process enables water to be activated

Peer-Reviewed Publication

University of Münster

Water splitting

image: A hydrogen atom (H) from water (H2O) is transferred to a phosphine-water radical cation under the supply of light energy (LED). This important radical intermediate can further transfer the hydrogen atom (white) to the substrate. The blue regions indicate the electron spin distribution. view more 

Credit: Christian Mück-Lichtenfeld

Hydrogen is seen as an energy source of the future – at least, when it is produced in a climate-friendly way. Hydrogen can also be important for the production of active ingredients and other important substances. To produce hydrogen, water (H2O) can be converted into hydrogen gas (H2) by means of a series of chemical processes. However, as water molecules are very stable, splitting them into hydrogen and oxygen presents a big challenge to chemists. For it to succeed at all, the water first has to be activated using a catalyst – then it reacts more easily. A team of researchers led by Prof. Armido Studer at the Institute of Organic Chemistry at Münster University (Germany) has developed a photocatalytic process in which water, under mild reaction conditions, is activated through triaryl phosphines and not, as in most other processes, through transition metal complexes.

This strategy, which has now been published in the “Nature” journal, will open a new door in the highly active field of research relating to radical chemistry, says the team. Radicals are, as a rule, highly reactive intermediates. The team uses a special intermediate – a phosphine-water radical cation – as activated water, from which hydrogen atoms from H2O can be easily split off and transferred to a further substrate. The reaction is driven by light energy. “Our system,” says Armido Studer, “offers an ideal platform for investigating unresearched chemical processes which use the hydrogen atom as a reagent in synthesis.”

Dr. Christian Mück-Lichtenfeld, who analysed the activated water complexes using theoretical methods, says, “The hydrogen-oxygen bond in this intermediate is extraordinarily weak, making it possible to transfer a hydrogen atom to various compounds.” Dr. Jingjing Zhang, who carried out the experimental work, adds: “The hydrogen atoms of the activated water can be transferred to alkenes and arenes under very mild conditions, in so-called hydrogenation reactions.” Hydrogenation reactions are enormously important in pharmaceutical research, in the agrochemical industry and in materials sciences.


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