BH4 Ng+ (Ar-Rn): Viable Compounds with a B-Ng Covalent Bond.

In this work, we explore, using high-level calculations, the ability of BH4 + to interact with noble gases. The He system is energetically unstable, while the Ne system could only be observed at cryogenic temperatures. In the case of the Ar, Kr and Xe systems, all are energetically stable, even at room temperature. The different chemical bond descriptors reveal a covalent character between B and the noble gas from Ar to Rn. However, this interaction gradually weakens the multicentric bond between the boron atom and the H2 fragment. Thus, although BH4 Rn+ exhibits a strong covalent bond, it tends to dissociate at room temperature into BH2 Rn+ +H2 .

Exploring the potential energy surface of E2P4 clusters (E=Group 13 element): the quest for inverse carbon-free sandwiches.

Inverse carbon-free sandwich structures with formula E2P4 (E=Al, Ga, In, Tl) have been proposed as a promising new target in main-group chemistry. Our computational exploration of their corresponding potential-energy surfaces at the S12h/TZ2P level shows that indeed stable carbon-free inverse-sandwiches can be obtained if one chooses an appropriate Group 13 element for E. The boron analogue B2P4 does not form the D(4h)-symmetric inverse-sandwich structure, but instead prefers a D(2d) structure of two perpendicular BP2 units with the formation of a double B-B bond. For the other elements of Group 13, Al-Tl, the most favorable isomer is the D(4h) inverse-sandwich structure. The preference for the D(2d) isomer for B2P4 and D(4h) for their heavier analogues has been rationalized in terms of an isomerization-energy decomposition analysis, and further corroborated by determination of aromaticity of these species.

Influence of endohedral confinement on the electronic interaction between He atoms: a He2@C20H20 case study.

The electronic interaction between confined pairs of He atoms in the C(20)H(20) dodecahedrane cage is analyzed. The He-He distance is only 1.265 A, a separation that is less than half the He-He distance in the free He dimer. The energy difference between the possible isomers is negligible (less than 0.15 kcal mol(-1)), illustrating that there is a nearly free precession movement of the He(2) fragment around its midpoint in the cage. We consider that a study of inclusion complexes, such as the case we have selected and other systems that involve artificially compressed molecular fragments, are useful reference points in testing and extending our understanding of the bonding capabilities of otherwise unreactive or unstable species. A key observation about bonding that emerges uniquely from endohedral (confinement) complexes is that a short internuclear separation does not necessarily imply the existence of a chemical bond.

Bonding of xenon hydrides.

We have computed the structure and stability of the xenon hydrides HXeY (with Y = F, Cl, Br, I, CCH, CN, NC) using relativistic density functional theory (DFT) at ZORA-BP86/TZ2P level. All model systems HXeY studied here are bound equilibrium structures, but they are also significantly destabilized with respect to Xe and HY. We have analyzed the bonding in HXeY in order to arrive at a simple picture that explains the main trends in stability.