First decade of π-electronic ion-pairing assemblies

Abstract: The prologue and progress of π-electronic ion-pairing assemblies, including synthesis of π-electronic ions, preparation of ion pairs, fabrication of assemblies as crystals, gels and liquid crystals and their characteristic properties, are summarized.

“…In dipyrrolyldiketone BF 2 complexes, the inversion of the two pyrrole rings is required for anion binding because their stable conformations are not suitable for anion binding (Figure 1b). [2,3] Thus, the stability of the four conformations of 2 a-c in regard to the orientations of the pyrrole rings were examined by DFT calculations. [12] Similar to BF 2 complexes, the pyrrole-non-inverted structures were the most stable; the dipoles of pyrrole and core six-membered rings were oriented opposite to each other.…”

“…As π-electronic anion-responsive molecules, the BF 2 complexes of 1,3-dipyrrol-2-yl-1,3-propanediones (dipyrrolyldiketones) (e. g., 1 a-c, Figure 1a) form anion complexes and ionpairing assemblies when combined with cations (Figure 1b). [2][3][4][5] A variety of anion complexes (pseudo π-electronic anions) have been prepared by modifying the receptor pyrrole moieties. The tetrahedral boron unit in these anion complexes interferes with their effective stacking with the countercations and themselves.…”

Dipyrrolyldiketone Pt^II Complexes: Ion‐Pairing π‐Electronic Systems with Various Anion‐Binding Modes

“…In dipyrrolyldiketone BF 2 complexes, the inversion of the two pyrrole rings is required for anion binding because their stable conformations are not suitable for anion binding (Figure 1b). [2,3] Thus, the stability of the four conformations of 2 a-c in regard to the orientations of the pyrrole rings were examined by DFT calculations. [12] Similar to BF 2 complexes, the pyrrole-non-inverted structures were the most stable; the dipoles of pyrrole and core six-membered rings were oriented opposite to each other.…”

“…As π-electronic anion-responsive molecules, the BF 2 complexes of 1,3-dipyrrol-2-yl-1,3-propanediones (dipyrrolyldiketones) (e. g., 1 a-c, Figure 1a) form anion complexes and ionpairing assemblies when combined with cations (Figure 1b). [2][3][4][5] A variety of anion complexes (pseudo π-electronic anions) have been prepared by modifying the receptor pyrrole moieties. The tetrahedral boron unit in these anion complexes interferes with their effective stacking with the countercations and themselves.…”

Dipyrrolyldiketone Pt^II Complexes: Ion‐Pairing π‐Electronic Systems with Various Anion‐Binding Modes

“…It is also noteworthy that nitroarenes behave as electrophilic coupling partners for Suzuki–Miyaura coupling [ 14 ]. As the platforms for NO 2 substitution, dipyrrolyldiketone BF 2 complexes (e.g., 1a , b , Scheme 1 ) have been examined as anion-responsive π-electronic molecules [ 15 , 16 , 17 , 18 , 19 ], which formed anion complexes and ion-pairing assemblies in combination with cations [ 20 , 21 ]. Pyrrole β-substituents of 1b enable the facile and selective introduction of substituents at the α-positions, resulting in the synthesis of various derivatives [ 18 , 19 ].…”

Nitro-Substituted Dipyrrolyldiketone BF2 Complexes as Electronic-State-Adjustable Anion-Responsive π-Electronic Systems

“…In particular, π-electronic molecules with planar geometries may afford stacking assemblies, which are suitable for the generation of electrically conductive materials. Ion-pairing assemblies based on π-electronic ions form a variety of ordered states that act as dimension-controlled assemblies, such as crystals, liquid crystals, and supramolecular gels [ 2 , 3 ]. The preparation of π-electronic anions, which can serve as components of ion-pairing assemblies, is more difficult than that of π-electronic cations due to the lower stability of electron-rich species.…”

Supramolecular Assemblies of Dipyrrolyldiketone CuII Complexes