Oxidation of SO2 to SO3 by Cerium Oxide Cluster Cations Ce2O4+ and Ce3O6+

Role of H2O Adsorption in CO Oxidation over Cerium-Oxide Cluster Anions (CeO2)nO- (n = 1-4)

Water (H2O) is ubiquitous in the environment and inevitably participates in many surface reactions, including CO oxidation. Acquiring a fundamental understanding of the roles of H2O molecules in CO oxidation poses a challenging but pivotal task in real-life catalysis. Herein, benefiting from state-of-the-art mass-spectrometric experiments and quantum chemical calculations, we identified that the dissociation of a H2O molecule on each of the cerium oxide cluster anions (CeO2)nO- (n = 1-4) at room temperature can create a new atomic oxygen radical (O•-) that then oxidizes a CO molecule. The size-dependent reactivity of H2O-mediated CO oxidation on (CeO2)nO- clusters was rationalized by the orbital compositions (O2p) and energies of the lowest unoccupied molecular orbitals of active O•- radicals modified by H2O dissociation. Our findings not only provide new insights into H2O-mediated CO oxidation but also demonstrate the importance of H2O in modulating the reactivity of the O•- radicals.

Thermochemistry and mechanisms of the Pt+ + SO2 reaction from guided ion beam tandem mass spectrometry and theory

The kinetic energy dependences of the reactions of Pt⁺ (²D_5/2) with SO₂ were studied using a guided ion beam tandem mass spectrometer and theory. The observed cationic products are PtO⁺ and PtSO⁺, with small amounts of PtS⁺, all formed in endothermic reactions. Modeling the kinetic energy dependent product cross sections allows determination of the product bond dissociation energies (BDEs): D₀(Pt⁺-O) = 3.14 ± 0.11 eV, D₀(Pt⁺-S) = 3.68 ± 0.31 eV, and D₀(Pt⁺-SO) = 3.03 ± 0.12 eV. The oxide BDE agrees well with more precise literature values, whereas the latter two results are the first such measurements. Quantum mechanical calculations were performed for PtO⁺, PtS⁺, PtO₂ ⁺, and PtSO⁺ at the B3LYP and coupled-cluster with single, double, and perturbative triple [CCSD(T)] levels of theory using the def2-XZVPPD (X = T, Q) and aug-cc-pVXZ (X = T, Q, 5) basis sets and complete basis set extrapolations. These theoretical BDEs agree well with the experimental values. After including empirical spin-orbit corrections, the product ground states are determined as PtO⁺ (⁴Σ_3/2), PtS⁺ (⁴Σ_3/2), PtO₂ ⁺ (²Σ_g ⁺), and PtSO⁺ (²A'). Potential energy profiles including intermediates and transition states for each reaction were also calculated at the B3LYP/def2-TZVPPD level. Periodic trends in the thermochemistry of the group 9 metal chalcogenide cations are compared, and the formation of PtO⁺ from the Pt⁺ + SO₂ reaction is compared with those from the Pt⁺ + O₂, CO₂, CO, and NO reactions.

Geometrical Structures of Gas-Phase Cerium Oxide Cluster Cations after Reaction with Nitric Oxide Studied by Ion Mobility Mass Spectrometry

Cerium oxide cluster cations were reacted with nitric oxide molecules and then measured by ion mobility mass spectrometry (IMMS). Ce_nO_2n+1N⁺ species appeared as products of the reaction Ce_nO_2n⁺ + NO → Ce_nO_2n+1N⁺, and their collision cross sections (CCSs) with helium were obtained by IMMS. The experimental CCSs of Ce_nO_2n+1N⁺ were 2-6 Ų larger than those of Ce_nO_2n⁺ for n = 4-10. Geometrical structures of Ce₄O₉N⁺ and Ce₅O₁₁N⁺ were assigned by comparing experimental CCSs with theoretically calculated CCSs of candidate structures. The suggested structures showed that the adsorbed NO molecule is oxidized by the Ce_nO_2n⁺ cluster into a nitrite (NO₂^-) or nitrate (NO₃^-). The Ce_nO_2n+1N⁺ species are regarded as intermediates of the NO oxidation reaction Ce_nO_2n⁺ + NO → Ce_nO_2n-1⁺ + NO₂, and therefore, the present results are helpful for understanding redox reactions involving gas-phase Ce_nO_2n⁺ cluster ions.

Screening the activity of single-atom catalysts for the catalytic oxidation of sulfur dioxide with a kinetic activity model

An accurate prediction model of catalytic activity is crucial for both structure design and activity regulation of catalysts. Here, a kinetic activity model is developed to study the activity of single-atom catalysts (SACs) in catalytic oxidation of sulfur dioxide. Using the adsorption energy of the oxygen atom as a descriptor, the catalytic activities of 132 SACs were explored. Our results indicate the highest activity when the adsorption energy of oxygen equals -0.83 eV. In detail, single-atom Pd catalyst exhibits the best catalytic activity with an energy barrier of 0.60 eV. Most importantly, this work provides a new insight for developing a highly accurate and robust prediction model for catalytic activity.

A hybrid-DFT investigation of the Ce oxidation state upon adsorption of F, Na, Ni, Pd and Pt on the (CeO2)6 cluster

The formation of small polarons in CeO_2−x compounds has been investigated mainly on solids, compact surfaces, and large nanoparticles.