Structural Elucidation
of N2O Clusters
at Low Temperatures: Exemplary Framework Stabilized by π‑Hole-Driven
N···O and N···N Pnicogen Bonding Interactions
N2O is a classic prototype, in which central
nitrogen
is sufficiently electropositive with a positive potential of 20 kcal
mol–1 in magnitude to qualify it as a possible pnicogen.
This was applied to a test with N2O clusters using ab initio calculations in association with various molecular
topographic tools. The structure of the energetically dominant and
N2O dimer was in favor of a perpendicular geometry, where
the central nitrogen atom of the N2O submolecule assumed
a near 90° angle with the adjacent NO and/or NN
moiety, which provides the affirmation of central nitrogen as a possible
π-hole-driven pnicogen. The terminal nitrogen and oxygen atoms
of N2O continue to act as conventional electron donors
(Lewis bases) with a negative potential. Overall, predominant π-hole-driven
N···O and N···N pnicogen bonding interactions
were observed to stabilize N2O clusters. Furthermore, N2O clusters (dimers and trimers) were synthesized at low temperatures
in an Ar matrix using molecular beam (effusive and supersonic expansion)
experiments. The geometries of these clusters were characterized by
probing infrared spectroscopy with corroboration from ab initio computational methods. In addition to our previously investigated
nitromethane and nitrobenzene systems, N2O also makes it
to a pnicogen bonder’s club with the central nitrogen as a
π-hole-driven pnicogen.