Environmental Chemistry at BESSY II: Radicals in waterways
How the radical scavenger TEMPO traps a hydroxyl radical OH·. The proton of the hydroxyl radical reacts with TEMPO first. Colour coding: grey for C (carbon), white for H (hydrogen), red for O (oxygen) and blue for N (nitrogen). © HZB
How do radicals form in aqueous solutions when exposed to UV light? This question is important for health research and environmental protection, for example with regard to the overfertilisation of water bodies by intensive agriculture. A team at BESSY II has now developed a new method of investigating hydroxyl radicals in solution. By using a clever trick, the scientists gained surprising insights into the reaction pathway.
Hydroxyl radicals (OH·) are found everywhere, from the troposphere to the cells of the human body. There, they cause oxidative stress and accelerate the ageing process. They are also increasingly present in rivers and lakes, where they are formed by the photolysis of nitrogen oxides that have entered the water from over-fertilised soils. When UV radiation from sunlight strikes nitrogen oxides, hydroxyl radicals and a range of other radicals are generated. The chemistry of these radicals is extremely difficult to characterise accurately, as they react very quickly
A team led by Professor Alexander Föhlisch of the HZB has investigated the chemistry of hydroxyl radicals formed from nitrogen oxides in water using X-ray absorption spectroscopy at the BESSY II X-ray source.
‘We work with a liquid jet sample cell, in which we can study molecules in solution under highly realistic conditions. This is only possible at BESSY II,’ says Leo Cordsmeier, the study's first author. The scientists exploited the fact that certain molecules can ‘capture’ radicals. The molecule TEMPO is known as a radical scavenger for both carbon and nitrogen oxide radicals. ‘We use TEMPO here as a kind of trick,’ explains Cordsmeier. ‘It serves here as a “sensor” because this molecule is directly involved in the reaction and can be detected very easily in our experiment. This enables us to analyse the reaction of the OH radicals directly.'
In this way, they could observe, step by step, how radicals form in aqueous solutions containing nitrogen oxides when irradiated with UV light and how they are bound by TEMPO. In doing so, they also succeeded in measuring an unexpected intermediate state, enabling the reaction pathway to be reconstructed with precision. Their results show that the proton of the hydroxyl radical reacts with TEMPO first. ‘For the scavenging of hydroxyl radicals by TEMPO, we show that the mechanism does not proceed through a bound intermediate state between the two molecules, as has been proposed in the literature, but instead through an electron transfer. This is a surprising finding,' says Alexander Föhlisch. This study has enabled his team to develop a new method for investigating radicals in solution, allowing them to selectively observe where bonds break and new ones form.
- AI agents deliver results – but do they reason scientifically?A research team co-led by Kevin Maik Jablonka from the Helmholtz Institute for Polymers in Energy Applications Jena (HIPOLE Jena) and N. M. Anoop Krishnan from the Indian Institute of Technology Delhi has developed Corral, a new benchmark for AI agents in science. The preprint “AI scientists produce results without reasoning scientifically” has been published on arXiv (https://doi.org/10.48550/arXiv.2604.18805). The analysis shows that current systems can execute scientific workflows and deliver results; however, they often do not follow the basic principles of scientific testing and reasoning.
- Magnetic field during catalyst synthesis triples ammonia yieldApplying an external magnetic field during the synthesis of CoFe₂O₄ electrocatalysts triples the ammonia yield during electrocatalytic conversion. The magnetic field alters the surface states of the spinel oxide thin films, making catalytically active sites more accessible. In the journal 'Advanced Functional Materials', a team led by Marcel Risch at HZB and Sanjay Mathur at University of Cologne demonstrates a scalable strategy for developing next-generation electrocatalysts for efficient and sustainable chemical production.
- Materials chemistry shapes the future of catalysisThe synthesis of materials can serve as a tool for developing smart, adaptive electrocatalysts. This rapidly evolving field of research involves in-situ analytics, data-driven discoveries and autonomous robotics. These new approaches could accelerate the discovery of long-lasting and efficient catalysts for future energy conversion and the decarbonisation of the chemical industry. A recent article by Dr Prashanth Menezes and his team in the renowned journal Angewandte Chemie provides an overview of this research.