Crystallization Mechanisms Applied to Understand the Crystal Formation of Rotaxanes

Orlando, Tainára; Salbego, Paulo R. S.; Farias, Fellipe Freire Santos de; Weimer, Gustavo H.; Copetti, João P. P.; Bonacorso, Hélio G.; Zanatta, Nilo; Hoerner, Manfredo; Berná, José; Martins, Marcos A. P.

doi:10.1002/ejoc.201801870

Cited by 24 publications

(52 citation statements)

References 73 publications

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“…This result corroborates the behavior already observed in our previous study that proposed new descriptors, 16 and also when applied to some crystalline structures of rotaxanes. 23 The range of values for I D is somewhat narrow and indicates that the real minimum for this index should be somewhere between 0.6 and 0.7. Once again, this demonstrates that for a quantitative comparative index the sole use of the geometric parameter has its limitations.…”

Section: Results and Discussionmentioning

confidence: 98%

“…Recently, these indices have been used to compare crystalline structures of [2]rotaxanes. 23 The normalized data used allow the results to be compared between distinct crystalline structures. A multiparameter index (I mp ) was shown to be a quantitative index to assess the contribution of more than one considered parameter, e.g., a multiparameter index using geometry and contact area will be I DC .…”

Section: Introductionmentioning

confidence: 99%

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Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)

et al. 2019

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A systematic investigation to assess the degree of similarity between polymorphs was carried out. A similarity indices (I X ) approach was applied in ten series of polymorphs with different characteristics and number of molecules in the asymmetric unit. Geometric (I D ), contact area (I C ), and stabilization energy (I G ) parameters were used. It was possible to situate each comparison in different regions of similarity within the polymorphism phenomenon and determine the boundaries between quasi-isostructural polymorphs and polymorphs of low similarity. The multiparameter I DCG index was used as a robust tool to determine the total similarity within the polymorphism phenomenon. The highest contribution of the stabilization energy parameter (45%) toward the final value of similarity (I DCG ) was observed, followed by the contact area index (32%). The geometric index contributed approximately 23% to the final value of I DCG . This information reinforces the importance of the contact area and stabilization energy in assessing the degree of similarity between crystalline structures. A new descriptor (I Q ) based on the comparison of the energetic contribution of intermolecular interaction types present in each crystal structure is presented. I Q can be a versatile tool and applicable even for systems that do not share any similarity.

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Section: Results and Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)

et al. 2019

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“…To verify the intercomponent stabilization [ 52 , 53 , 54 , 55 , 56 , 57 ], rotaxanes with stronger π-stacking interaction were synthesized. Dialdehyde 1 was selected due to its conjugated aromatic structure.…”

Section: Resultsmentioning

confidence: 99%

π-Stacking Stopper-Macrocycle Stabilized Dynamically Interlocked [2]Rotaxanes

et al. 2021

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The synthesis of mechanically interlocked molecules is valuable due to their unique topologies. With π-stacking intercomponent interaction, e.g., phenanthroline and anthracene, novel [2]rotaxanes have been synthesized by dynamic imine clipping reaction. Their X-ray crystal structures indicate the π-stackings between the anthracene moiety (stopper) on the thread and the (hetero)aromatic rings at the macrocycle of the rotaxanes. Moreover, the length of glycol chains affects the extra π-stacking intercomponent interactions between the phenyl groups and the dimethoxy phenyl groups on the thread. Dynamic combinatorial library has shown at best 84% distribution of anthracene-threaded phenanthroline-based rotaxane, coinciding with the crystallography in that the additional π-stacking intercomponent interactions could increase the thermodynamic stability and selectivity of the rotaxanes.

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“…The interaction stabilization energies of each "furcated" system were obtained using the G AI analysis, following a procedure already reported in studies using different kind of molecules. [4,10,12,14,[23][24][25][26] The G AI analysis furnished the energy of each atom···atom interaction correlating Quantum Theory of Atoms in Molecules (QTAIM) data and intercomponent stabilization energy. The QTAIM provides a quantum description of the location and behavior of the atoms in a chemical bond.…”

Section: Resultsmentioning

confidence: 99%

“…In the past, the problem resided in obtaining crystals, and today, the difficulty lies in understanding how to systematically study the number of structures available. [2] Therefore, the search for approaches that investigate interactions in rotaxanes, especially in the crystalline state, presents a continuous challenge as this may lead to a significant impact in designing systems with desired properties, [3,4] which are mainly affected by several intercomponent interactions. Nevertheless, there is a lack of studies in the literature regarding these interactions in the crystalline state.…”

Section: Introductionmentioning

confidence: 99%

[2]Rotaxanes Bearing a Tetralactam Macrocycle: The Role of a Trifurcated Hydrogen Bond in the Crystalline State

et al. 2019

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This study investigated the proper classification and quantification of intercomponent trifurcated hydrogen bonds, in the crystalline state, of rotaxanes bearing a tetralactam Leigh‐type macrocycle. Quantum mechanical calculations were carried out to obtain the interaction paths and their stabilization energies. In general, the use and necessity of fragmentation in types of interaction have been reported in the literature, although they are commonly performed only using a geometric approach. This results in N–H···O interactions that are indicated as the main interactions between components, neglecting other possible interactions. The use of energetic fragmentation was demonstrated here under an appropriate demarcation considering all interactions and showing the existence and role of the C–H···O interaction. The C–H···O interactions showed similar energy to N–H···O interactions with average values around –4.75 kcal mol–1 and –4.60 kcal mol–1, respectively. This revealed that the three hydrogen bonds are part of a cooperative set of interactions with a similar contribution. The trifurcated hydrogen bonds presented high contribution in the total intercomponent stabilization energy of the rotaxanes, with an average value of 51 % in the studied series.

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Crystallization Mechanisms Applied to Understand the Crystal Formation of Rotaxanes

Cited by 24 publications

References 73 publications

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)

π-Stacking Stopper-Macrocycle Stabilized Dynamically Interlocked [2]Rotaxanes

[2]Rotaxanes Bearing a Tetralactam Macrocycle: The Role of a Trifurcated Hydrogen Bond in the Crystalline State

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Crystallization Mechanisms Applied to Understand the Crystal Formation of Rotaxanes

Cited by 24 publications

References 73 publications

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (IX)

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (IX)

π-Stacking Stopper-Macrocycle Stabilized Dynamically Interlocked [2]Rotaxanes

[2]Rotaxanes Bearing a Tetralactam Macrocycle: The Role of a Trifurcated Hydrogen Bond in the Crystalline State

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Product

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Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)

Supramolecular Similarity in Polymorphs: Use of Similarity Indices (I^X)