We will demonstrate that the combination of non-contact atomic force microscopy (NC-AFM) and Kelvin probe force microscopy (KPFM) can be used to quantify the adsorption/desorption characteristics of fundamental gases in heterogeneous catalysis at the single nanoparticle (NP) level as a function of NP size, shape, composition and temperature, and how properties are affected by the oxide support. Furthermore, we will explicitly demonstrate that KPFM is capable of quantifying phenomena of contamination and dissolution at single NPs that is most important for many catalytic processes.While NC-AFM will be used to reveal the surface structure and morphology determined by the size, shape, distribution and sintering of NPs, the task of KPFM will be to monitor the local electronic structure determined by changes in the NP's work function (WF) providing a quantitative measure for adsorbed molecular species or dissolved atomic species in NPs. The techniques will be established as calibrated standard tools in heterogeneous model catalysis involving metal NPs. Local measurements by NC-AFM and KPFM will be supported by an analysis with X-ray photoelectron spectroscopy (XPS) and Ultraviolet photoelectron spectroscopy (UPS) to obtain the chemical fingerprints and average WF of the molecule-NP- surface system. Experiments will be backed by density functional theory (DFT) analysing and predicting the adsorption of reactants on NPs and related WF changes. The ultimate and challenging goal is to observe and to quantify simple reactions at single NPs, namely the oxidation of CO and the hydrogenation of hydrocarbons.For the project, we will first focus on pure NPs of platinum group materials (PGMs), in particular on palladium (Pd) and gold (Au), commonly used for industrial catalytic converters. Furthermore, we consider bi-metallic NPs with the focus on Pd and Au. During the course of the project, we optionally consider other metals like Fe, Co or Cu. The support will be ultra-thin and thick films of cerium oxide (ceria).The adsorption and desorption of CO, oxygen, hydrogen and simple hydrocarbon gases (e.g. ethylene) will be investigated in detail; species that are known to adsorb at metal nanoparticles like PdNPs. Contamination experiments will focus in particular on carbon contamination and dissolution, phenomena most relevant for many catalytic reactions like the hydrogenation of hydrocarbons, Fischer-Tropsch process and in the synthesis of carbon structures like graphene or nanotubes.

DFG Programme Research Grants

International Connection France

Cooperation Partner Privatdozent Dr. Clemens Barth