Symmetry-Dependent Intermolecular π–π Stacking Directed by Hydrogen Bonding in Racemic Copper-Phenanthroline Compounds

Abstract: We examine the role of molecular symmetry and hydrogen bonding in determining heterochiral intermolecular π–π stacking motifs in four racemic compounds with the formula [Cu­(phen)2(H2O)]­[MF6]·xH2O (M = Ti, Zr, Hf; phen = 1,10-phenanthroline) and two racemic compounds with the formula Cu­(phen)2MF6·H2O (M = Zr, Hf). In this work, equimolar combinations of C 2-symmetric Δ- and Λ-Cu­(phen)2(H2O)2+ complexes were found to organize via only face-to-face π–π stacking interactions to adopt a new horizontal packing m… Show more

“…However, the symmetry of the Cu cations is reduced to C 1 owing to the large tilt of the apical bound water ligand. Similar symmetry reduction in five-coordinated Cu complexes were also reported in compounds with Cu­(phen) 2 (H 2 O) 2+ cations and Cu­(phen) 2 MF 6 (phen = 1,10-phenanthroline; M = Zr, Hf) molecules. , In addition, the angles between the Cu atom and centroids of the ligands are quite different between the two unique cations, with Cation 1 being 151.41° and Cation 2 being 169.82° (Figure a). Notably, the angle in Cation 2 is distinctly larger than the rest of cations in this study.…”

“…The parallel heterochiral π–π stacking interactions in compounds 1– 5 can be explained by the steric effect of the methyl groups on the ligands, in that the bulk methyl groups favors parallel stacking to minimize free volume . Similar parallel heterochiral π–π packings were observed in racemic compounds with other methyl-substituted ligands and the aromatic ligand 1,10-phenanthroline, and an inversion center is always found between the racemates. ,, As a result, although the asymmetric unit of the discussed compounds contains equivalent BBUs, the BBUs are related by different symmetry elements, resulting in different extended structures. The racemic chains display a similar pattern but have different compositions between the NCS and CS structures.…”

Beyond π–π Stacking: Understanding Inversion Symmetry Breaking in Crystalline Racemates

“…However, the symmetry of the Cu cations is reduced to C 1 owing to the large tilt of the apical bound water ligand. Similar symmetry reduction in five-coordinated Cu complexes were also reported in compounds with Cu­(phen) 2 (H 2 O) 2+ cations and Cu­(phen) 2 MF 6 (phen = 1,10-phenanthroline; M = Zr, Hf) molecules. , In addition, the angles between the Cu atom and centroids of the ligands are quite different between the two unique cations, with Cation 1 being 151.41° and Cation 2 being 169.82° (Figure a). Notably, the angle in Cation 2 is distinctly larger than the rest of cations in this study.…”

“…The parallel heterochiral π–π stacking interactions in compounds 1– 5 can be explained by the steric effect of the methyl groups on the ligands, in that the bulk methyl groups favors parallel stacking to minimize free volume . Similar parallel heterochiral π–π packings were observed in racemic compounds with other methyl-substituted ligands and the aromatic ligand 1,10-phenanthroline, and an inversion center is always found between the racemates. ,, As a result, although the asymmetric unit of the discussed compounds contains equivalent BBUs, the BBUs are related by different symmetry elements, resulting in different extended structures. The racemic chains display a similar pattern but have different compositions between the NCS and CS structures.…”

Beyond π–π Stacking: Understanding Inversion Symmetry Breaking in Crystalline Racemates

“…The MF 6 2À anions with hydrogen-bonded water molecules are interlaced between the racemic chains to form the extended three-dimensional structure. Compared to other molecular compounds with MF 6 2À anions in an extended and complicated hydrogen network (Gautier et al, 2012;Nisbet et al, 2020Nisbet et al, , 2021, the MF 6 2À anions in (I) and (II) experience less distortion because the hydrogen-bonding contacts are less extensive and only occur along the same axis due to the site symmetry of hydrogen-bonding interactions (Kunz & Brown, 1995;Halasyamani, 2004).…”

Crystal structures of two copper(I)–6,6′-dimethyl-2,2′-bipyridyl (dmbpy) compounds, [Cu(dmbpy)₂]₂[MF₆]·xH₂O (M = Zr, Hf; x = 1.134, 0.671)

“…The centroid–centroid distances between the aromatic rings and the perpendicular distances between the phen planes are 3.599–4.008 and 3.351–3.412 Å, respectively. Such a stacking pattern suggests the existence of π–π interactions between the two phen ligands of two neighboring hybrid clusters . From the perspective of the whole structure, each cluster interacts with four neighboring ones through intermolecular π–π stacking along two perpendicular directions (Figure S7).…”

“…Such a stacking pattern suggests the existence of π−π interactions between the two phen ligands of two neighboring hybrid clusters. 34 From the perspective of the whole structure, each cluster interacts with four neighboring ones through intermolecular π−π stacking along two perpendicular directions (Figure S7). S3), which help to stabilize the hybrid cluster structure.…”

A Tellurium-Substituted Heteropolyniobate with Unique π–π Stacking and Ionic Conduction Property