Charge Density Studies of Weak Interactions in Dipicrylamine

Woźniak, Krzysztof; Mallinson, P. R.; Wilson, Chick C.; Hovestreydt, E.; Grech, E.

doi:10.1021/jp014733x

Cited by 38 publications

(32 citation statements)

References 26 publications

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“…in a comparison with the σ‐hole on halogens and it explains the orthogonal geometry. Charge density analysis showed the presence of interaction lines and bond critical points (bcp) for such interactions, even at distances longer than the sum of van der Waals (vdW) contacts . Both types (σ‐ and π‐hole) are very similar in nature and the importance of the latter has been highlighted by Frontera and co‐workers .…”

Section: Introductionmentioning

confidence: 90%

“…Both types (σ‐ and π‐hole) are very similar in nature and the importance of the latter has been highlighted by Frontera and co‐workers . Carbonyl⋅⋅⋅ carbonyl contacts, studied by Diederich and co‐workers, and nitro⋅⋅⋅nitro orthogonal interactions, studied by Wozniak and co‐workers, are typical examples of such π‐hole‐based synthons. Carbonyl⋅⋅⋅carbonyl contacts in crystalline aldehydes are even more exciting as they are less studied from a crystal engineering perspective and certainly not in any property engineering of solids.…”

Section: Introductionmentioning

confidence: 95%

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σ‐Hole and π‐Hole Synthon Mimicry in Third‐Generation Crystal Engineering: Design of Elastic Crystals

Saha

Desiraju

2017

Chemistry A European J

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Crystal engineering of organic molecular solids has been practiced for the last 50 years or so and it is convenient to divide the chronology of its progress into three generations of effort (Figure 1a). First generation crystal engineering was about recognizing that there is a connection between crystal structure and crystal property. The term "Crystal Engineering" was invoked more as a challenge as to how one could go about designing a particular crystal structure. This first stage also saw development of various models that explained observed crystal structures in terms of the packing features and/or intermolecular interactions involved. Second generation crystal engineering dealt with the actual strategy and logic driven methodology of crystal design; the concept of the supramolecular synthon is crucial to the planning of crystal synthesis.[1] But there was no prediction of a property. Here we have tried to take a step in this direction and to utilize predesigned modular structures to modulate properties[2] and exemplified with hand-twisted helical crystals,[3] finding importance in different fields such as negative-index invisible materials, enantiosensitive plasmonic sensors, lithography techniques, chiroptic materials. A stepwise design strategy from one-dimensional (1D) plastic crystal → 1D elastic crystals → two-dimensional (2D) elastic → 2D plastic crystals is outlined. This type of 2D plasticity represents a new generation of bendable crystals in which plastic behavior is seen with a fair degree of isotropic character in the crystal packing. The presence of two sets of bendable faces, generally orthogonal to each other, allows for the possibility of hand twisting of the crystals to give grossly helical morphologies (Figure 1b). Accordingly, we propose the name hand-twisted helical crystals for these substances. In third generation crystal engineering a solid state property may be obtained through supramolecular synthon based logic driven design rather than merely by optimizing a crystal property that is obtained from an isolated serendipitous result.

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Section: Introductionmentioning

confidence: 90%

Section: Introductionmentioning

confidence: 95%

σ‐Hole and π‐Hole Synthon Mimicry in Third‐Generation Crystal Engineering: Design of Elastic Crystals

Saha

Desiraju

2017

Chemistry A European J

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“…Recently, crystal structures of DPA and a computational study on the intermolecular interactions observed in the crystal structure have been reported. [1] The crystal structures of some of its organic salts have also been reported.…”

Section: Dipicrylaminementioning

confidence: 99%

Selective Precipitation of Alkaline Earth Metal Cations with Dipicrylamine Anion: Structure–Selectivity Correlation

et al. 2006

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“…Similar non-bonded attractive interactions have been reported. [23] Binding Studies with DMSO and DMF In our attempt to resolve the 1 H NMR spectroscopic signals for the urea protons in receptors 2 and 3, the spectra for the respective receptors were recorded in [D 6 ]DMSO and [D 7 ]DMF. In both cases, broad and apparently downfield-shifted bands were observed.…”

Section: Resultsmentioning

confidence: 99%

Influence of Urea N–H Acidity on Receptor–Anionic and Neutral Analyte Binding in a Ruthenium(II)–Polypyridyl‐Based Colorimetric Sensor

et al. 2009

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A new ruthenium(II)-polypyridyl complex {[Ru(bpy) 2 L]2+ ; bpy = 2,2Ј-bipyridyl, L = 1-(6-nitro-1,10-phenanthrolin-5-yl)-3-phenylurea} having a urea functionality as a receptor fragment for anionic analytes was synthesized. Its binding affinity towards various oxy anions and halides was studied. This complex was found to act as a selective colorimetric sensor for F -among halides and CH 3 COO -/H 2 PO 4 -among oxy anions. The relative binding affinity of different anions towards this receptor was examined by using quantum chemical calculations. This complex was also found to act as a colorimetric sensor for neutral molecules like DMSO and

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Charge Density Studies of Weak Interactions in Dipicrylamine

Cited by 38 publications

References 26 publications

σ‐Hole and π‐Hole Synthon Mimicry in Third‐Generation Crystal Engineering: Design of Elastic Crystals

σ‐Hole and π‐Hole Synthon Mimicry in Third‐Generation Crystal Engineering: Design of Elastic Crystals

Selective Precipitation of Alkaline Earth Metal Cations with Dipicrylamine Anion: Structure–Selectivity Correlation

Influence of Urea N–H Acidity on Receptor–Anionic and Neutral Analyte Binding in a Ruthenium(II)–Polypyridyl‐Based Colorimetric Sensor

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