Project description
New approach to exploring water and oxide surface interaction
The interaction between water and oxide surfaces plays an important role in many technological applications and environmental processes. However, gaining a fundamental understanding of processes at water–oxide interfaces is challenging because of the complexity of the systems. The EU-funded WatFun project takes a radically new approach in exploring this interaction at the atomic scale – which is the most fundamental – by integrating bulk liquid water into ultrahigh vacuum setups, where an arsenal of highly developed techniques is available to investigate surfaces. This project will help scientists focus on providing a fresh view on environmentally relevant chemistry.
Objective
The water/oxide interface, and the molecular processes that happen there, regulate everything from environmental chemistry and the sequestration of CO2 to the cohesion of man-made structures. The properties of individual surface sites govern reactivity, so probing chemistry at this level is necessary to better understand natural processes, and to ultimately improve technologies where this interface plays a central role. In this project, we take a radically new approach to investigate the water/oxide interface at the most fundamental, the atomic, scale: we have found a way to integrate bulk liquid water into ultrahigh vacuum (UHV) setups, where an arsenal of highly-developed techniques is available to investigate surfaces. This provides the opportunity to accurately determine fundamental quantities that were hitherto inaccessible, and to obtain clear-cut experimental results for interpreting and predicting molecular-scale processes. In this project, we seize this opportunity to develop novel measurement concepts, and apply them to minerals. Following a broad work plan we will: measure the surface tension of neat water and the surface free energies of solids with unprecedented purity; devise a method to determine, site-by-site, the intrinsic proton affinity, the fundamental property that determines the point of zero charge of oxides in solutions, and their Brønsted acidity in gas-phase reactions; investigate, at the atomic scale, how liquid water affects surface structure, and how oxides become hydroxylated, dissolve, and ‘age’; discover how ice nucleates on the mineral aerosol surfaces that are crucial in cloud formation; study how dissolved CO2 reacts with natural minerals, which affects the global carbon cycle; address the hydrated oxides that form the basis of cements in concrete. While this project focuses on providing a fresh view on environmentally-relevant chemistry, we also show how our approach can make an impact in a much wider range of areas.
Fields of science
Keywords
Programme(s)
Topic(s)
Funding Scheme
ERC-ADG - Advanced GrantHost institution
1040 Wien
Austria