posted on 2012-08-08, 00:00authored byMoira Ciardi, Francesca Tancini, Guzmán Gil-Ramírez, Eduardo C. Escudero Adán, Chiara Massera, Enrico Dalcanale, Pablo Ballester
We describe the design, synthesis and conformational
assignment
of three diasteromeric bis-phosphonate cavitands based on an aryl
extended calix[4]pyrrole tetrol scaffold. The diastereoisomers differ
in the relative spatial orientation of the PO groups installed
at their upper rims. We demonstrate that these compounds act as heteroditopic
receptors for ion pairs forming ion-paired 1:1 complexes with alkylammonium
(quaternary and primary) chloride salts in dichloromethane (DCM) solution
and in the solid-state. 1H NMR titrations indicate that
the complexes are highly stable thermodynamically and kinetically.
In the case of tetraalkyl-phosphonium/ammonium chloride guests, the
host featuring the two PO groups directed outwardly with respect
to the aromatic cavity, 4oo, produces the most thermodynamically
stable complexes. Conversely, for the primary alkyl ammonium chloride,
the most effective receptor is the diastereoisomer 4ii with the two PO groups converging on top of the aromatic
cavity. In the nonpolar DCM solvent, the size of the quaternary cation
has a strong impact in the thermodynamic stability of the complexes
and their binding geometry. We use 2D-ROESY experiments to map out
the binding geometries of the 1:1 complexes formed in solution. The
1:1 complexes of the 4oo host with the chloride salts
have a separated arrangement of the bound ion-pair.
In contrast, those of the 4ii host display a close-contact arrangement. We also investigate the same
complexation processes in acetonitrile (ACN) solution. Both the salt
and the initially formed anionic complex are fully dissociated in
this more polar solvent. The receptors show an analogous trend in
their binding affinities for quaternary phosphonium/ammonium chloride
salts to the one seen in DCM solution. However, in ACN solution, the
magnitudes of the binding affinities are reduced significantly and
the size of the cation does not play a role. In addition, the inversion
in the trend of relative binding affinities of the complexes, which
was revealed in DCM solution, is eradicated in ACN when changing the
cation substitution from quaternary to primary.