6533b7d0fe1ef96bd125a2ed

RESEARCH PRODUCT

Confinement inside a Crystalline Sponge Induces Pyrrole To Form N−H⋅⋅⋅π Bonded Tetramers

Mengling WuJunle ZhangLiangqian YuanFangfang PanKari Rissanen

subject

Models MolecularCrystallography X-Ray010402 general chemistry01 natural sciencesCatalysiskemialliset sidoksetchemistry.chemical_compoundTetramerpyrrole tetramersupramolekulaarinen kemiaconfinement effectcrystalline sponge methodhost-guest chemistryMoleculePyrrolesHost–guest chemistryConfined spacePyrroleamiinitbiology010405 organic chemistryChemistryOrganic ChemistryIntermolecular forceGeneral Chemistrypolymeriabiology.organism_classification0104 chemical sciencesSpongeCrystallographyZigzagröntgenkristallografiaaggregatio

description

Based on the DFT‐level calculated molecular volume (V mol ) of pyrrole and its liquid density, pyrrole manifests the highest liquid density coefficient LD c (defined as [V mol • density • 0.6023]/FW) value of 0.7. Normal liquids have LD c < 0.63. This very high LD c is due to the strong N‐H … π interactions in solution and hence pyrrole can be considered to be a pseudo‐crystalline liquid. When trapped inside the confined space of the crystalline sponge a reorientation of the N‐H … π interaction is observed leading to specific cyclic N‐H … π tetramers and N‐H … π dimers, verified by single crystal X‐ray crystallographic and computational methods. These tetramers are of the same size as four pyrrole molecules in the solid‐state of pyrrole, yet the cyclic N‐H … π intermolecular interactions are circularly oriented instead of the linear zig‐zag structure found in the X‐ray structure of a solid pyrrole. The confinement thus acts as an external driving force for the tetramer formation. peerReviewed

yearjournalcountryeditionlanguage
2021-06-01Chemistry – A European Journal
https://doi.org/10.1002/chem.202100087