Halogen Bonding inside
a Molecular Container
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Abstract
The synthetic macrocycle cucurbit[6]uril forms host–guest
inclusion complexes with molecular dibromine and diiodine. As evidenced
by their crystal structures, the encapsulated dihalogens adapt a tilted
axial geometry and are held in place by two different types of halogen-bonding
interactions, one with a water molecule (bond distances 2.83 Å
for O···Br and 3.10 Å for O···I)
and the other one with the ureido carbonyl groups of the molecular
container itself (bond distances 3.33 Å for O···Br
and 3.49 Å for O···I). While the former is of
the conventional type, involving the lone electron pair of an oxygen
donor, the latter is perpendicular, involving the π-system of
the carbonyl oxygen (N–CO···X dihedrals
ca. 90°). Such perpendicular interactions resemble those observed
in protein complexes of halogenated ligands. A statistical analysis
of small-molecule crystal structural data, as well as quantum-chemical
calculations with urea as a model (MP2/aug-cc-pVDZ-PP), demonstrates
that halogen bonding with the π-system of the carbonyl oxygen
can become competitive with the commonly favored lone-pair interaction
whenever the carbonyl group carries electron-donating substitutents,
specifically for ureas, amides, and esters, and particularly when
the lone pairs are engaged in orthogonal hydrogen bonding (<i>h</i>X bonds). The calculations further demonstrate that the
perpendicular interactions remain significantly attractive also for
nonlinear distortions of the O···X–X angle to
ca. 140°, the angle observed in the two reported crystal structures.
The structural and theoretical data jointly support the assignment
of the observed dihalogen–carbonyl contacts as genuine halogen
bonds