Polymer Network-Stabilized Liquid Crystals

Dierking, Ingo

doi:10.1002/(sici)1521-4095(200002)12:3<167::aid-adma167>3.0.co;2-i

Cited by 305 publications

(255 citation statements)

References 49 publications

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“…Inspired by nature, molecular self-assembly that is directed through weak, noncovalent interactions has received tremendous attention for the development of systems with ordered structures and resultant functions [1,2,6,7]. Th ese eff orts have resulted in various functional materials based on self-assembled structures including solutions, elastomers, gels and hard materials [1,2,[7][8][9].Gels as a functional system is an emerging fi eld in themselves, possessing a responsiveness to external stimuli such as stress, light, temperature, pH and ionic strength [10]. Gels with molecular assemblies can be produced in organic solvent (organogels) or aqueous solvent (hydrogels).…”

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confidence: 99%

Hydrogels with self-assembling ordered structures and their functions

Gong

2011

NPG Asia Mater

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Biomimetic and bioinspired materials are receiving increasing attention because of their robust functionality and potential applications as artifi cial tissue [1,2]. For natural materials, a high degree of sophistication is achieved through self-organization of the various components into ordered and hierarchical structures following a well-defi ned pattern [2][3][4]. Biological tissue possesses these ordered structures, endowing the living organisms with mechanical toughness and functionality, as exemplifi ed by tissues such as bone and cartilage. Th erefore, eff orts should be made to introduce ordered and hierarchical structure into soft, and also hard, synthetic materials. Among the strategies developed to date, self-assembly is a convenient and powerful method for producing ordered structures [5].Self-assembly, the spontaneous organization of discrete components into organized structures, is widespread in nature, such as in protein folding and hybridization of the DNA double helix [3][4][5][6]. Self-assembled structures usually incorporate additional functionalities. For example, phospholipids form a lipid bilayer arou nd the cell as a barrier to the diffusion of ions and proteins, and tropocollagens self-assemble into fi brils collagens that are closely packed in parallel arrays in the tendon, endowing it with excellent mechanical properties [3]. Inspired by nature, molecular self-assembly that is directed through weak, noncovalent interactions has received tremendous attention for the development of systems with ordered structures and resultant functions [1,2,6,7]. Th ese eff orts have resulted in various functional materials based on self-assembled structures including solutions, elastomers, gels and hard materials [1,2,[7][8][9].Gels as a functional system is an emerging fi eld in themselves, possessing a responsiveness to external stimuli such as stress, light, temperature, pH and ionic strength [10]. Gels with molecular assemblies can be produced in organic solvent (organogels) or aqueous solvent (hydrogels). In this review, we focus primarily on functional hydrogels with self-assembled structures. Functional organogels produced by molecular self-assembly have been covered in several excellent reviews [11][12][13][14].Hydrogels as a functional material have their own advantages over organogels. Th e aqueous medium makes hydrogels an ideal candidate for soft biotissue, mimicking its functions for applications such as scaff olds for cell culturing [15,16]. However, producing structured hydrogels is not easy because the ordered structure formation and water content (which introduces fl uctuation) work in opposite directions. Th e typical kinds of molecules capable of forming self-assembled structures in aqueous media are amphiphile, block-copolymer and liquid-crystalline (LC) molecules. Under certain conditions, the ordered structures formed by molecular self-assembly can be frozen in physically or chemically crosslinked hydrogels with additional functionalities, such as anisotropic optical and mechanica...

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confidence: 99%

Hydrogels with self-assembling ordered structures and their functions

Gong

2011

NPG Asia Mater

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“…[232][233][234][235][236] LC GELS Two types of LC gels have been reported: LC chemical gels and LC physical gels (Figure 14a). While LC chemical gels are composed of conventional liquid crystals (liquid crystal solvent) and cross-linked LC polymers, 239,240 for LC physical gels, liquid crystals are mixed with low-molecular weight gelators that form self-assembled fibrous networks. 241,242 The resulting materials exhibit elastic mechanical Functional liquid-crystalline polymers T Kato et al properties compared to conventional liquid crystals, but preserve the dynamics and stimuli-responsive properties of small molecules of liquid crystals.…”

Section: Functional Lc Polymers and Networkmentioning

confidence: 99%

“…In the LC chemical gels, the gelation is achieved by the in situ crosslinking of polymerizable mesogens dissolved in a LC solvent. 239,240 The presence of mesogenic groups attached to polymer networks provides the proper miscibility with the mesogens trapped by a 3D polymer network. Owing to their dynamic properties, LC chemical gels have been widely investigated for their application to optical devices.…”

Section: Functional Lc Polymers and Networkmentioning

confidence: 99%

Functional liquid-crystalline polymers and supramolecular liquid crystals

Kato

Uchida

Ichikawa

et al. 2017

Polym J

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The design and functions of liquid-crystalline (LC) polymers with classifying them into conventional-, supramolecular-, dendriticand network-type LC polymers are described. LC polymers show new functions as new devices in the field of energy and environment by incorporating mesogenic moieties exhibiting photonic, electronic and ionic functions. Supramolecular LC polymers show dynamic and unique properties because the mesogenic moieties are built with non-covalent interactions. Dendritic-type LC polymers exhibit liquid crystallinity by nanosegregation of aromatic and aliphatic moieties. Dendritic fork-like mesogens have also been prepared. A variety of nonmesogeic functional building blocks including fullerene, π-conjugated moieties, catenane, rotaxane and others can be incorporated into LC phases by attaching these dendritic moieties. LC networks are constructed in situ polymerization of polymerizable nematic or nanostructured liquid crystals. The specific characteristics of the LC networks have generated new research trends to develop well-defined polymers that exhibit optical, transport and separation properties. In these materials, through suitable design of LC monomers, the preservation of smectic, columnar and bicontinuous cubic phases has been successfully used for the development of membranes with one-dimensional, two-dimensional and three-dimensional nanostructures.

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“…Insbesondere der kürzlich gelungene Nachweis einer spontanen Polarisation in Phasen achiraler Moleküle, den so genannten "Bananenmolekülen", hat ein weites Feld für zukünftige Forschung eröffnet. Anwendungstechnisch könnten neben den oben aufgeführten Technologien auch der DHF-Effekt (deformed helix ferroelectrics) sowie polymer-disperse und -stabilisierte FLC [9] interessant werden. Dabei bleibt zu hoffen, dass die zukünftige industrielle Entwicklung neuer Produkte, basierend auf (ferroelektrischen) Flüssig-kristallen, nicht ausschließlich in asiatischen Ländern stattfindet, sondern auch dort, wo ein nicht geringer Teil der Grundlagenforschung an diesen Systemen geleistet wird.…”

Section: Ausblickunclassified

Ferroelektrische Flüssigkristalle: Binär schaltbare Flüssigkristalle eignen sich für schnellere Displays

Dierking

2000

Phys. Bl.

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Flüssigkristall‐Anzeigen sind heute in jedem Haushalt zu finden, von einfachen monochromen Taschenrechner‐ und Uhren‐Displays bis hin zu hochauflösenden Farbdisplays in portablen Computern, Kameras und Camcordern. Ihr Vorteil gegenüber anderen Anzeigeelementen liegt in der flachen Bauweise sowie geringen Leistungsaufnahme. Neben der Blickwinkelabhängigkeit liegt ein Nachteil der heute verwendeten nematischen Flüssigkristalle in ihren relativ langsamen Schaltzeiten, die eine echte Video‐Tauglichkeit bislang verhindern. Abhilfe können Displays auf der Basis ferroelektrischer Flüssigkristalle schaffen, die eine deutliche Verbesserung des Blickwinkels, erhöhten Kontrast und Schaltzeiten im μs‐Bereich aufweisen.

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Polymer Network-Stabilized Liquid Crystals

Cited by 305 publications

References 49 publications

Hydrogels with self-assembling ordered structures and their functions

Hydrogels with self-assembling ordered structures and their functions

Functional liquid-crystalline polymers and supramolecular liquid crystals

Ferroelektrische Flüssigkristalle: Binär schaltbare Flüssigkristalle eignen sich für schnellere Displays

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