Imaging and characterization of activated CO2 species on Ni(110)

By means of a joint experimental and theoretical approach we provide single molecule imaging and characterization of CO2 on Ni(110), chemisorbed with high charge transfer from the substrate in an activated state that plays a crucial role in the hydrogenation process. Low-temperature scanning tunneling microscopy images of single CO2 molecules are combined with ab initio density-functional-theory calculations, where dispersive forces and zero-point energy estimates have been explicitly accounted for. We obtain a detailed characterization of the adsorption geometries and an estimate of the energies corresponding to the different adsorbed states. A consistent picture of CO2 chemisorption on Ni(110) is provided on the basis of the newly available information, yielding a deeper insight into the previously existing spectroscopic and theoretical data.

Imaging and characterization of activated CO2 species on Ni(110)

Characterization and prediction of peptide structures on inorganic surfaces

Investigating Tetrel-Based Neutral Frustrated Lewis Pairs for Hydrogen Activation

Uncovering the Activity of Alkaline Earth Metal Hydrogenation Catalysis Through Molecular Volcano Plots

Uncovering the Activity of Alkaline Earth Metal Hydrogenation Catalysis Through Molecular Volcano Plots

Characterization and prediction of peptide structures on inorganic surfaces

Investigating Tetrel-Based Neutral Frustrated Lewis Pairs for Hydrogen Activation