Litcius/Paper detail

Probing catalyst-free hydroxyl radical generation at microbubble interfaces

Siyu Yang, Wei Wang, Jie‐Jie Chen, Joseph S. Francisco, Xian‐Wei Liu

2025Nature Communications20 citationsDOIOpen Access PDF

Abstract

Gas–liquid interfaces at the micro- and nanoscale are emerging hotspots for unique chemical reactivity, yet the reactivity of individual microbubbles remains largely unexplored. Here, we visualize the catalyst-free generation of reactive oxygen species, particularly hydroxyl radicals, at the gas‒liquid interface of microbubbles. In-situ chemiluminescence imaging, together with spectroscopic analyses, and multiscale computational simulations shows that the enrichment of hydroxide ions at the microbubble surface, coupled with the interfacial electric field, drives the catalyst-free generation of hydroxyl radicals. The generated hydroxyl radicals enable efficient degradation of organic pollutants and facilitate the conversion of nitrogen into nitrate ions under mild conditions, highlighting the practical applicability of this catalyst-free process in environmental remediation and sustainable nitrogen fixation. These findings provide new insights into catalyst-free radical chemistry at gas–liquid interfaces, with significant implications for catalytic processes, sustainable chemical manufacturing, and environmental catalysis. Microbubble interfaces exhibit unique chemical reactivity. Here, the authors visualize catalyst-free hydroxyl radical generation at nitrogen microbubbles, enabling pollutant degradation and sustainable nitrogen fixation under mild conditions.

Topics & Concepts

RadicalHydroxyl radicalSonochemistryCatalysisPollutantReactivity (psychology)HydroxideMaterials sciencePhotochemistryIonChemistryNanoscopic scaleChemical engineeringChemical processNitrogenNanotechnologyChemical reactionChemiluminescenceNanoparticleDegradation (telecommunications)NitrateEnvironmental remediationIn situReactive nitrogen speciesProcess (computing)Environmental chemistryOxygen evolutionMinerals Flotation and Separation TechniquesCatalytic Processes in Materials Sciencenanoparticles nucleation surface interactions