Inversion symmetry and local vs. dispersive interactions in the nucleation of hydrogen bonded cyclic n-mer and tape of imidazolecarboxamidines

Sihui Long,Venkatraj Muthusamy,Peter G Willis,Arthur Cammers,Sean Parkin

doi:10.3762/bjoc.4.23

Abstract

Substitutional changes to imidazolecarboxamidine that preserved intermolecular hydrogen bonding in the solid state were used to study the relationship between packing and the hydrogen bond motif. Various motifs competed, but the most common imidazolecarboxamidine crystalline phase was a Ci symmetric dimer that established inversion centers by associating enantiomeric tautomers. Counter to intuition, the calculated gas-phase energies per molecule of the solid state atomic coordinates of the Ci dimer motifs were higher than those of the C1 dimer, trimer, tetramer and tape motifs, while the packing densities of Ci dimers were found to be higher. This result was interpreted as an enhanced ability of the Ci dimers to pack. If other motifs competed, the hydrogen bonds and conformations should be lower in energy than the Ci dimer. The results detail the effect of packing on the conformation in these molecules. The results are interpreted as a rough measure of the energetic compromise between packing and the energies related to the coordinates involving one dihedral angle and hydrogen bonding. The results establish a connection between solution and solid phase conformation.

Highlights

Bonding in organic compounds and nuances inherent in crystal packing engender boundless diversity in the arrangements of hydrogen bonded organic solid states
The paradox that hydrogen bonding is important as both an element of structural diversity and design vanishes given that diversity depends on maximizing the number of hydrogen bonding options available to molecules whereas design focuses on controlling the direction and minimizing the number of hydrogen bonds
Figure 1: 1: An intuitive prediction regarding the relationship between crude hydrogen bond donor/acceptor directionality and hydrogen bond molecularity. 2: The amidine and imidazole moieties are not coplanar due to steric interactions; the CN–CN dihedral angle (50–90°) directs hydrogen bond vectors. 3: Imidazole prefers the tape. 4: This tautomer/rotamer is not observed

Summary

Introduction

Bonding in organic compounds and nuances inherent in crystal packing engender boundless diversity in the arrangements of hydrogen bonded organic solid states. Large angles between hydrogen bond donor and acceptor, as in 3, should predispose solid state tapes [13], whereas small angles should prefer dimers. To simplify the interplay between directionality and the motif of the crystalline phase n-mer we studied a molecule with one hydrogen bond donor and one acceptor.

Results

Conclusion