We report a joint photoelectron spectroscopic and theoretical study of the PtAl(-) and PtAl2(-) anions. The ground state structures and electronic configurations of these species were identified to be C∞v, (1)Σ(+) for PtAl(-), and C2v, (2)B1 for PtAl2(-). Structured anion photoelectron spectra of these clusters were recorded and interpreted using ab initio calculations. Good agreement between theory and experiment was found. All experimental features were successfully assigned to one-electron transitions from the ground state of the anions to the ground or excited states of the corresponding neutral species.

We report a joint photoelectron spectroscopic and theoretical study of the PtZnH5(-) cluster anion. This cluster exhibited an unprecedented planar pentagonal coordination for Pt and an unusual stability and high intensity in the mass spectrum. Both are due to the σ-aromaticity found in the H5-cycle supported by the 5d orbitals on the Pt atom. σ-Aromaticity in all-H systems has been predicted in the past but never found in experimentally observed species. Besides fundamental importance, mixed transition-metal hydrides can be found as intermediates in catalytic processes, and thus, the unexpected stability facilitated by σ-aromaticity can be appreciated also in practical applications.

While boride clusters of alkali and transition metals have been observed and extensively characterized, so far little is known about lanthanide-boron clusters. Lanthanide-boride solids are intriguing, however, and therefore it is of interest to understand the fundamental electronic properties of such systems, also on the subnano scale. We report a joint experimental photoelectron spectroscopic and theoretical study of the SmB₆^- anion, iso-stoichiometric to the SmB₆ solid-a topological Kondo insulator. The cluster is found to feature strong static and dynamic electron correlations and relativistic components, calling for treatment with CASPT2 and up sixth-order Douglass-Kroll-Hess (DKH) relativistic correction. The cluster has a C_2v structure and covalent Sm-B bonds facilitated by f atomic orbitals on Sm, which are typically thought to be contracted and inert. Additionally, the cluster retains the double antiaromaticity of the B₆^2- cluster.

Anion photoelectron spectroscopic and theoretical studies were conducted for the PdH(-) and PdH3 (-) cluster anions. Experimentally observed electron affinities and vertical detachment energies agree well with theoretical predictions. The PdH3 (-) anionic complex is made up of a PdH(-) sub-anion ligated by a H2 molecule, in which the H-H bond is lengthened compared to free H2. Detailed molecular orbital analysis of PdH(-), H2, and PdH3 (-) reveals that back donation from a d-type orbital of PdH(-) to the σ* orbital of H2 causes the H-H elongation, and hence, its activation. The H2 binding energy to PdH(-) is calculated to be 89.2 kJ/mol, which is even higher than that between CO and Pd. The unusually high binding energy as well as the H-H bond activation may have practical applications, e.g., hydrogen storage and catalysis.

Mass spectrometric analysis of the anionic products of interaction between bimetallic palladium-copper tetrahydride anions, PdCuH₄^-, and carbon dioxide, CO₂, in a reaction cell shows an efficient generation of the PdCuCO₂H₄^- intermediate and formate/formic acid complexes. Multiple structures of PdCuH₄^- and PdCuCO₂H₄^- are identified by a synergy between anion photoelectron spectroscopy and quantum chemical calculations. The higher energy PdCuH₄^- isomer is shown to drive the catalytic hydrogenation of CO₂, emphasizing the importance of accounting for higher energy isomers for cluster catalytic activity. This study represents the first example of CO₂ hydrogenation by bimetallic hydride clusters.

Organophosphonates are used as chemical warfare agents, pesticides, and corrosion inhibitors. New materials for the sorption, detection, and decomposition of these compounds are urgently needed. To facilitate materials and application innovation, a better understanding of the interactions between organophosphonates and surfaces is required. To this end, we have used diffuse reflectance infrared Fourier transform spectroscopy to investigate the adsorption geometry of dimethyl methylphosphonate (DMMP) on MoO3, a material used in chemical warfare agent filtration devices. We further applied ambient pressure X-ray photoelectron spectroscopy and temperature programmed desorption to study the adsorption and desorption of DMMP. While DMMP adsorbs intact on MoO3, desorption depends on coverage and partial pressure. At low coverages under UHV conditions, the intact adsorption is reversible. Decomposition occurs with higher coverages, as evidenced by PCHx and POx decomposition products on the MoO3 surface. Heating under mTorr partial pressures of DMMP results in product accumulation.