Geminal Bis-ureas as Gelators for Organic Solvents: Gelation Properties and Structural Studies in Solution and in the Gel State

Schoonbeek, Franck S.; Esch, Jan H. van; Hulst, Ron; Kellogg, Richard M.; Feringa, Ben L.

doi:10.1002/1521-3765(20000717)6:14<2633::aid-chem2633>3.3.co;2-c

Cited by 62 publications

(89 citation statements)

References 5 publications

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“…297e In contrast, the bis(pyridylurea) component ( Figure 71) did not gel polar organic or organic−aqueous solvent owing to the presence of gel-inhibiting HB between pyridyl and urea groups, which prevented the formation of the infinite urea α-tape motif. 299 In the presence of 1,4-diiodoperfluorobenzene, gelation of polar organic−water mixtures has also been reported. Gelation was attributed to XB formation between polarized iodine atoms and XB acceptor pyridyl subunits, as shown by the 1:1 single-crystal X-ray structure (Figure 71a).…”

Section: Solid-state Architecturesmentioning

confidence: 99%

Halogen Bonding in Supramolecular Chemistry

et al. 2015

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CONTENTS 1. Introduction to Halogen Bonding 7119 1.1. Nature of the Halogen Bond 7119 1.2. Scope of the Review 7120 2. Computational and Theoretical Investigations of Halogen Bonding 7120 2.1.Quantum Mechanics Methods 7120 2.2. σ-Hole Model of Halogen Bonding 7120 2.3. Other Contributions to the Nature of Halogen Bonding 7122 2.4. Recent Examples of Computationally Investigated Halogen-Bonded Complexes 7123 2.4.1. XB to Neutral Species 7123 2.4.2. XB to Anions 7126 2.4.3. XB in Protein−Ligand Complexes 7127 2.4.4. Electron-Transfer Processes Affected by XB Interactions 7127 2.5. Classical Force Field Calculations 7127 2.6. Conclusions and Outlook 7129 3. Gas-Phase Studies of Halogen-Bonding Interactions 7130 4. Halogen Bonding in the Solid State 7131 4.1. Introduction to Crystal Engineering and Functional Materials 7131 4.2. Fundamentals 7132 4.3. Halogen-Bonding Hierarchy 7134 4.3.1. Ranking Halogen-Bond Donors 7134 4.3.2. HB/XB Complementarity/Competition 7136 4.3.3. Predicting XBs 7138 4.4. Control of Solid-State Supramolecular Architectures 7138 4.4.1. Polymorphism 7138 4.4.2. Stoichiometry 7139 4.4.3. Tautomeric Control 7140 4.4.4. XBs Involving Metals and Metal-Bound XBs 7140 4.4.5. XB with Anions in the Solid State 4.5. Solid-State Architectures 4.6.

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Section: Solid-state Architecturesmentioning

confidence: 99%

Halogen Bonding in Supramolecular Chemistry

et al. 2015

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“…As shown in Figure 5, m = 10, 12, 14 was chosen as an example to test its liquid crystal properties by POM, and birefringence was observed in all polymers. The gelation process may be based on a subtle balance between solubility and insolubility, 15,16 which requires to possessing both moderate affinity with solvent molecules and the moderate self-aggregation ability. In the case of aromatic solvents, the good compatibility between biphenyl mesogens group and aromatic solvents may destroy the π-π interaction of biphenyl mesogens, resulting in the aggregation among biphenyl mesogens that did not occur on cooling.…”

Section: Rheological Measurementsmentioning

confidence: 99%

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confidence: 99%

Organic gels prepared from side‐chain liquid crystalline polymers without the spacer

Chen

Yuan

et al. 2017

Polymers for Advanced Techs

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A series of side-chain liquid crystal polymers (SCLCPs) without the spacer, named poly[ω-(4′-nalkyl oxybiphenyl-4-oxy)methacrylate (PMBiCm, m = 1,2,4,6,8,10,12,14,16,and 18), have been synthesized. The novel polymer organogels were prepared by introducing PMBiCm into common organic solvents. Solubility and gel properties of polymer organogelators differ widely according to the nature of the solvents. In aromatic solvents, PMBiCm completely dissolved in solvent due to good compatibility between biphenyl mesogen group and aromatic solvents.Poly[ω-(4′-n-alkyl oxybiphenyl-4-oxy)methacrylate were still insoluble in polar solvents such as acetone, ethanol, DMF, ethylene glycol, and n-butanol. This behavior resulted from mismatch of solubility parameter between PMBiCm and solvent. Considering the factors of solvent, we have systematically studied 3 organic solvents with different polarities (butyl acetate, n-butyl amine, and n-heptane). It is found that the length of the alkoxy tail chain of the SCLCPs has significant influence on gelability and gel thermal stability. In further studies discussed by UV-Vis spectroscopy, the results revealed that the π-π stacking interaction of the biphenyl mesogens might be the key factor for guiding the self-assembly processes and the polymer gel formation.This work is useful to comprehending physical mechanism of polymer organogels. Meanwhile, those expand SCLCPs to a wide range of applications. KEYWORDS alkoxy tail chain length, organogel, side-chain liquid crystalline polymer

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“…5. Long fibers form and these, if entangled, lead to gels rather than crystals [38][39][40]. The coils formed lead to gelation of organic solvents.…”

Section: Aggregation In Supersaturated Solutionsmentioning

confidence: 99%

Dutch Resolution of Racemates and the Roles of Solid Solution Formation and Nucleation Inhibition

Kellogg

Kaptein

Vries

2007

Topics in Current Chemistry

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An overview is given of the principles of Pasteur resolutions via separation of diastereomeric salts.Thereafter, primary nucleation processes of (chiral) organic compounds in supersaturated solution are consideredfollowed by crystal growth in the presence of tailor-made additives. A representative example of a DutchResolution is presented, the concept of families of resolving agents is defined and examples are given.The phenomenon of reversed Dutch Resolution, resolution of mixtures of families of racemates, is illustrated.The roles of both solid solution formation and nucleation inhibition in Dutch Resolution are discussed.The work is concluded with the results of a broadly based search for nucleation inhibitors for phenylethylamine as resolving agent. This search can serve as a model for the discovery of nucleation inhibitorsfor other resolving agents. The specific role of bifunctional family members of resolving agents as possiblenucleation inhibitors is also discussed.

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Geminal Bis-ureas as Gelators for Organic Solvents: Gelation Properties and Structural Studies in Solution and in the Gel State

Cited by 62 publications

References 5 publications

Halogen Bonding in Supramolecular Chemistry

Halogen Bonding in Supramolecular Chemistry

Organic gels prepared from side‐chain liquid crystalline polymers without the spacer

Dutch Resolution of Racemates and the Roles of Solid Solution Formation and Nucleation Inhibition

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