Title: Structure and Chemical State of Cesium on Well-Defined Cu(111) and Cu₂O/Cu(111) Surfaces

The deposition of cesium (Cs) onto the metallic and oxidized surfaces of Cu(111) was investigated using scanning tunneling microscopy (STM), X-ray photoelectron spectroscopy (XPS), and density functional theory calculations (DFT) to elucidate the properties of alkali metals when supported on metal and oxide surfaces. At low coverages, cesium adopts partially cationic (Cs^δ+), highly mobile, and likely atomic structures on the metal surface of Cu(111). Such structures are not observable at room temperature using STM due to rapid surface mobility but can be quantified using XPS. This is further verified by DFT calculations which show that Cs adsorption on Cu(111) is site insensitive, where atop, bridge, and hollow sites yield identical adsorption energy. Reaction with O₂ (1 × 10^–7 Torr) at room temperature of the Cs/Cu(111) surface results in both CsO_x and Cu_xO formation, initially from the Cs sites and Cu step edges and then subsequently encompassing the terraces. Here, the presence of Cs promotes the oxidation process by O₂, and we have identified the oxidized Cs^δ+ and Cu¹⁺ using XPS. In contrast to the metallic substrate, the deposition of Cs onto the preoxidized surface of Cu₂O/Cu(111) allows for the anchoring of the oxidized Cs^δ+ nanostructures (few nm) which appear indiscriminately on the oxide surface with high dispersion and low mobility. While clearly distinguishable using STM, we have revealed a rich geometric heterogeneity of the nanostructures of Cs on Cu₂O/Cu(111), likely templated through a strong interaction between the Cs and the Cu₂O substrate. In addition, it is also evident that Cs imparts a destabilizing effect on the ordered oxide substrate, as observed through the increase of surface defects. Finally, the thermal stability of the Cs structures was studied, using sequential annealing steps revealing that Cs remained stable up to 550 K with some loss of both cesium and oxygen at higher temperatures of 650 K. DFT calculations show that unlike Cu(111), the adsorption energy of Cs on Cu_xO/Cu(111) is highly dependent on adsorption site, and electronic effects enabled through the interaction between Cs, O, and Cu.