Hydrate and Alcoholate Forms of Phosphomolybdic Heteropolyacid and Their Formation under Conditions of Isothermal Sorption of Water,Methanol, and Ethanol Vapors

Reaction of water, methanol, and ethanol vapors with a solid phosphomolybdic acid at room temperature is accompanied by formation of bulk hydrates and alcoholates. The reaction involves several stages which are readily detected by the sorption and desorption isotherms. The formation of alcoholates causes loosening of the acid lattice, thus favoring much more active initial sorption of alcohols, compared with water, and liquefaction once H₃PMo₁₂O₄₀·11.5CH₃OH and H₃PMo₁₂O₄₀·14.7C₂H₅OH compositions are attained.     

Towards relativistic ECP / DFT description of chemical bonding in E112 compounds: spin-orbit and correlation effects in E112X versus HgX (X=H, Au)

The relativistic effective core potential (RECP) approach combined with the spin-orbit DFT electron correlation treatment was applied to the study of the bonding of eka-mercury (E112) and mercury with hydrogen and gold atoms. Highly accurate small-core shape-consistent RECPs derived from Hartree-Fock-Dirac-Breit atomic calculations with Fermi nuclear model were employed. The accuracy of the DFT correlation treatment was checked by comparing the results in the scalar-relativistic (spin-orbit-free) limit with those of high level scalar-relativistic correlation calculations within the same RECP model. E112H was predicted to be slightly more stable than its lighter homologue (HgH). The E112-Au bond energy is expected to be ca. 25–30 % weaker than that of Hg-Au. The role of correlations and magnetic (spin-dependent) interactions in E112-X and Hg-X (X=H, Au) bonding is discussed. The present computational procedure can be readily applied to much larger systems and seems to be a promising tool for simulating E112 adsorption on metal surfaces.     

Importance of spin-orbit effects on the isomerism profile of Au3: an ab initio study

Two-component relativistic density functional theory combined with high-level ab initio correlation techniques was applied to the study of the electronic structure and isomerism of Au(3). All calculations were performed with accurate small-core shape-consistent relativistic pseudopotentials. Density functional theory was used to determine the equilibrium structures of the Au(3) isomers and isomerization path and to estimate the contributions of spin-orbit effects to the ground state electronic energy along the path. The reliability of these estimates was verified through independent many-body multipartitioning perturbation theory calculations. Spin-orbit corrections were used to refine the isomerization energy profile computed by spin-orbit-free coupled cluster methods.