Anomalous Halogen–Halogen Interaction Assists Radial Chromophoric Assembly

Niyas, M. A.; Vijay, Vishnu; Sebastian, Ebin; Hariharan, Mahesh

doi:10.1021/jacs.8b13754

Cited by 40 publications

(64 citation statements)

References 56 publications

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“…Depending on the angle between the two CÀX•••Y-ÀC (X = Br and Y = Br/O) units ( Figure 6), these interactions are classified as type I( symmetrical interactions with q 1 % q 2 )a nd type II (bent interactions with q 1 %1808 and q 2 % 908). [23,24] In the case of 1,t wo molecules in the 1D layer (shown in the same color) interactw ith an intermolecular Br A sareference, the sum of the van der Waals radii of two Br atoms has been found to be 3.74 . [22] The 1D arrangement in 2 involves type Ii ntermolecular Br Finally,i n9 only the Br atoms at the bay positionsp articipate in type IB r •••Oh alogen-bonding interactions with q 1 and q 2 values of approximately 163 and approximately 1748 (Figure 8d).…”

Section: Single-crystal X-ray Crystallographymentioning

confidence: 99%

Halogen‐Bonded Assemblies of Arylene Imides and Diimides: Insight from Electronic, Structural, and Computational Studies

Mandal

Bansal

Kumar

et al. 2020

Chemistry A European J

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Halogen‐bonding interactions in electron‐deficient π scaffolds have largely been underexplored. Herein, the halogen‐bonding properties of arylene imide/diimide‐based electron‐deficient scaffolds were studied. The influence of scaffold size, from small (phthalimide) to moderately sized (pyromellitic diimide or naphthalenediimides) to large (perylenediimide), axial‐group modification, and number of halo substituents on the halogen bonding and its self‐assembly was probed in a set of nine compounds. The structural modification leads to tunable optical and redox properties. The first reduction potential E1/21 ranges between −1.09 and −0.17 V (vs. SCE). Two of the compounds, that is, 6 and 9, have deep‐lying LUMOs with values reaching −4.2 eV. Single crystals of all nine systems were obtained, which showed Br⋅⋅⋅O, Br⋅⋅⋅Br, or Br⋅⋅⋅π halogen‐bonding interactions, and a few systems are capable of forming all three types. These interactions lead to halogen‐bonded rings (up to 12‐membered), which propagate to form stacked 1D, 2D, or corrugated sheets. A few outliers were also identified, for example, molecules that prefer C−H⋅⋅⋅O hydrogen bonding over halogen bonding, or noncentrosymmetric rather than centrosymmetric organization. Computational studies based on Atoms in Molecules and Natural Bond Orbital analysis provided further insight into the halogen‐bonding interactions. This study can lead to a predictive design tool‐box to further explore related systems on surfaces reinforced by these weak directional forces.

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Section: Single-crystal X-ray Crystallographymentioning

confidence: 99%

Halogen‐Bonded Assemblies of Arylene Imides and Diimides: Insight from Electronic, Structural, and Computational Studies

Mandal

Bansal

Kumar

et al. 2020

Chemistry A European J

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“…For certain fields of materials chemistry,i ti so fu tmost importance to control the molecular self-assembly in the solid state. [13][14][15][16][17][18] However,o ther supramolecular interactions, such as dipole-dipole interactions and p-p stacking are less directing than for example, hydrogen bonds and are therefore harder to control and predict. [13][14][15][16][17][18] However,o ther supramolecular interactions, such as dipole-dipole interactions and p-p stacking are less directing than for example, hydrogen bonds and are therefore harder to control and predict.…”

Section: Introductionmentioning

confidence: 99%

“…There are structurally motifs, such as hydrogen or halogen bonds, [10][11][12] that are of high directionality and,t herefore, often used in crystal engineering. [13][14][15][16][17][18] However,o ther supramolecular interactions, such as dipole-dipole interactions and p-p stacking are less directing than for example, hydrogen bonds and are therefore harder to control and predict. [19][20][21] This is unfortunate, because the kind of arrangement of extended p sys-tems to each other is responsible for charget ransfer in organic electronic devices, such as organic field-effectt ransistors (OFETs).…”

Section: Introductionmentioning

confidence: 99%

Triptycene End‐Capped Quinoxalinophenanthrophenazines (QPPs): Influence of Substituents and Conditions on Aggregation in the Solid State

Ueberricke

Holub

Kranz

et al. 2019

Chemistry A European J

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Triptycene end-capped quinoxalinophenanthrophenazine reveals ac oplanar arrangementw ith ah igh overlap of the p planes. Fours tructurally relatedm odel compounds bearing electron-withdrawingo r-donating groups were synthesized,a nd their optoelectronic properties were characterized by using cyclovoltammetry,a bsorption-and emission spectroscopy as well as theoretical calculations. The directional robustness of the triptycene end-capping of these compounds was tested by using single-crystal X-ray diffraction. The impact of solvents and crystallization conditions has also been investigated.I nt otal, 17 single-crystal structures were obtained. Each structurew as evaluated for its potential charge-transfer capability taking into account the overall molecular packing, solvent enclathration and the structuralo verlap of the p planes of adjacent molecules. For this purpose, charge-transfer integrals were also calculated for every p-stacked dimer.Supporting information and the ORCID identification number (s) for the author(s) of this articlecan be found under: https://doi.

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“…Our persistent efforts towards comprehending the origin of anomalous crystalline architectures of distorted polyaromatics and twisted bichromophores motivated us to analyze the energetically favored pattern adopted by core-twisted octabrominated perylenediimide (OBPDI) upon crystallization, followed by exploring potential applications of the resultant crystalline motif. [25][26][27][28][29] Bay-halogenated perylenediimides (such as OBPDI) exhibit ac onformational chirality generated by the sterically induced twisting of the p-core and feature as ignificant activation barrier (DG°3 03 K %98 kJ mol À1 for chloro-substituted perylenediimide) for the interconversion between the axially chiral enantiomers. [30][31][32] The P/M isomers of the OBPDI chromophore assembled as independent stacks to yield highly symmetric racemic crystals from the parent solution.…”

Section: Introductionmentioning

confidence: 99%

Metastable Chiral Azobenzenes Stabilized in a Double Racemate

et al. 2020

Self Cite

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The self‐assembly of chiral organic chromophores is gaining huge significance due to the abundance of supramolecular chirality found in natural systems. We report an interdigitated molecular assembly involving axially chiral octabrominated perylenediimide (OBPDI) which transfers chiral information to achiral aromatic moieties. The crystalline two‐component assemblies of OBPDI and electron‐rich aromatic units were facilitated through π‐hole⋅⋅⋅π donor–acceptor interactions, and the charge‐transfer characteristics in the ground and excited states of the OBPDI cocrystals were established through spectroscopic and theoretical techniques. The OBPDI cocrystals entail a remarkable homochiral segregation of P and M enantiomers of both molecular entities in the same crystal system, leading to twisted double‐racemic arrangements. Synergistically engendered cavities with the stored chiral information of the twisted OBPDI stabilize higher‐energy P/M enantiomers of trans‐azobenzene through non‐covalent interactions.

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Anomalous Halogen–Halogen Interaction Assists Radial Chromophoric Assembly

Cited by 40 publications

References 56 publications

Halogen‐Bonded Assemblies of Arylene Imides and Diimides: Insight from Electronic, Structural, and Computational Studies

Halogen‐Bonded Assemblies of Arylene Imides and Diimides: Insight from Electronic, Structural, and Computational Studies

Triptycene End‐Capped Quinoxalinophenanthrophenazines (QPPs): Influence of Substituents and Conditions on Aggregation in the Solid State

Metastable Chiral Azobenzenes Stabilized in a Double Racemate

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