Nature of noncovalent carbon-bonding interactions derived from experimental charge-density analysis

Abstract

In an effort to better understand the nature of noncovalent carbon-bonding interactions, we undertook accurate high-resolution X-ray diffraction analysis of single crystals of 1,1,2,2-tetracyanocyclopropane. We selected this compound to study the fundamental characteristics of carbon-bonding interactions, because it provides accessible σ holes. The study required extremely accurate experimental diffraction data, because the interaction of interest is weak. The electron-density distribution around the carbon nuclei, as shown by the experimental maps of the electrophilic bowl defined by a (CN)2 CC(CN)2 unit, was assigned as the origin of the interaction. This fact was also evidenced by plotting the Δ(2) ρ(r) distribution. Taken together, the obtained results clearly indicate that noncovalent carbon bonding can be explained as an interaction between confronted oppositely polarized regions. The interaction is, thus electrophilic-nucleophilic (electrostatic) in nature and unambiguously considered as attractive.

Keywords: ab initio calculations; charge density; noncovalent carbon bonding; supramolecular chemistry; σ-hole interactions.