Chirality and Macroscopic Polar Order in a Ferroelectric Smectic Liquid-Crystalline Phase Formed by Achiral Polyphilic Bent-Core Molecules

Dantlgraber, Gert; Eremin, Alexey; Diele, Siegmar; Hauser, A.; Kresse, H.; Pelzl, G.; Tschierske, Carsten

doi:10.1002/1521-3757(20020703)114:13<2514::aid-ange2514>3.0.co;2-5

Cited by 61 publications

(65 citation statements)

References 28 publications

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“…One of them is that under polarizing microscope, we see no chiral domains of opposite handedness in the ground state of the DC phase. As we discussed, the DC phase consists of SmCP structure with short range interlayer correlation length [10][11][12][13][14][15][16][17][18][19]. The absence of opposite handed domains in our sample indicates two possibilities for the ground state arrangement of the layers: The adjacent layers are either homochiral (SmC s P S or SmC a P A type), making the overall structure chiral, though the opposite handed domains are smaller than the wavelength of the visible light.…”

Section: Discussionmentioning

confidence: 99%

“…During this process a simultaneous reversal in the polarization and the tilt direction takes place giving rise to a switching from SmC s P A to SmC a P S and SmC a P A to SmC s P S . Bent-core mesogens are well known for the optically isotropic phases they exhibit, which include the B4 phase [7][8][9], the dark conglomerate (DC) [10][11][12][13][14][15][16][17][18][19] and the dark enantiomeric (DE) phases [20]. The DC phase, which is the topic of interest of this paper, is usually found to occur below the isotropic phase.…”

Section: Introductionmentioning

confidence: 99%

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Unusual electric-field-induced transformations in the dark conglomerate phase of a bent-core liquid crystal

et al. 2014

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Unusual behaviour of the dark conglomerate (DC) phase seen in an oxadiazole-based achiral bent-core liquid crystal, which has not previously been reported for the DC phase of other liquid crystals, is described. Under polarizing optical microscopy, we see no domains of opposite handedness in the ground state of the DC phase. However, it shows unusual transformations when an electric field is applied to the system: On increasing the electric field, at first the domains of opposite handedness become visible and then they grow in size and slowly the sample transforms to a monochiral or single handed form which is followed by a nonchiral state at very high fields. The threshold electric fields required to achieve these changes are temperature dependent and the transformations are seen irrespective of the frequency of the applied electric field (100 Hz to 5 kHz), type of the waveform (sine, square and triangular) and the thickness (1.5 µm to 15 µm) or the geometry (planar and twisted) of the device used. Further, there is no field-induced high birefringence texture observed even though sufficiently large electric field (~22 V/µm) has been applied across the devices. The nature of the behaviour is investigated by various techniques such as optical microscopy, conoscopy, circular dichroic and Raman spectroscopies, electro-optics and dielectric spectroscopy. The possible physical phenomena behind these changes are discussed in detail.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Unusual electric-field-induced transformations in the dark conglomerate phase of a bent-core liquid crystal

et al. 2014

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“…The in-layer frustration caused by orthogonal tilting of the molecular segments can be relieved by the saddle-splay curvature: in three dimensions, the DC phases have significant negative Gaussian curvature. Depending on the local structure, the DC phases are classified as liquid crystalline sponge-like phases [28][29][30][31][32][33][34][35][36][37] and Helical Nano-Filament (HNF) phases or B4 phases [38][39][40]. In addition to these, a number of DC phases with intermediate or distinct nanostructures have been observed [41][42][43][44][45][46][47][48].…”

Section: Dark Conglomerate Phasesmentioning

confidence: 99%

Dark conglomerate phases of bent-core liquid crystals

Nagaraj

2016

Liquid Crystals

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Spontaneous or induced chiral symmetry breaking in achiral systems is unusual and understanding the origin of such a phenomenon has been an important area of research for several years. The optically isotropic mesophases exhibited by unconventional liquid crystals are one of the most interesting systems to investigate spontaneous chiral symmetry breaking in liquid crystal mesophases formed by achiral moieties. The dark conglomerate (DC) phases are one such optically isotropic family of phases. In this paper, a detailed account of the tendency of bent-core mesogens to form a variety of polar smectic phases, the formation of DC phases due to layers deformations and the general optical, electrical, physical properties of the DC phases are given. An example of a dark conglomerate phase which exhibit distinct electro-optic properties is described with the nature of dynamics of the response and physical reasons responsible for such behaviour. The challenges and prospects of the dark conglomerate phases are discussed for their potential applications in novel devices.

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“…Incorporation of a perfluorinated chain segment or silicon-containing unit (e.g., siloxane and carbosilane) into the hydrocarbon chain as an end group is useful to modulate mesophase properties. It was reported that mesophase stabilization was observed for bent-core molecules including two partially perfluorinated tails [36,94], and bent-core molecules incorporating nanosegregated siloxane end groups into one or two tails display a transformation from AF to FE switching [95].…”

Section: General Molecular Structure Of Bent-core Lcsmentioning

confidence: 99%

“…The Tschierske group reported that incorporation of terminal siloxane units at one tail of bent-core molecules leads to a transition from AF to FE switching [95]. A large number of such molecules including siloxane and carbosilane units were subsequently reported [134][135][136][137][138][139][140][141][142][143][144][145][146][147], and many of them exhibit DC phases with surface-stabilized bistable FE switching.…”

Section: Tilted Polar Smectic (Smcp) Phasesmentioning

confidence: 99%

Electric‐ and Light‐Responsive Bent‐Core Liquid Crystals: From Molecular Architecture and Supramolecular Nanostructures to Applications

Zhang¹

2013

Intelligent Stimuli‐Responsive Materials

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The three classic states of matter are well known and ubiquitous in everyday life: solid, liquid, and gas. Liquid crystals (LCs), an intermediate state between solid crystal and isotropic liquid, constitute a new fascinating class of condensed soft matter uniquely combining both fluidity and long-range order. The fluid-like mobility enables LCs to be switchable under external stimuli, and crystal-like long-range order bestows anisotropic physical properties on LCs. LCs can be divided into two main classes: thermotropic and lyotropic. Thermotropic LCs consist of individual molecules (or ion pairs) and exhibit phase transitions with the change of temperature. In this case, temperature is the fundamental thermodynamic factor determining mesophase formation. Lyotropic LCs are a special type of solution system that can form mesophases as a function of both temperature and concentration of LC molecules. The building block of a lyotropic phase is an aggregate (called a micelle) formed via self-assembly of many molecules (typically on the order of 100). Examples of LCs can be found both in the natural world and in technological applications. Thermotropic LCs find 189 190 ELECTRIC-AND LIGHT-RESPONSIVE BENT-CORE LIQUID CRYSTALS a wide variety of uses in displays, and an important example of lyotropic LCs is cell membranes formed by amphiphilic lipids. Surfactants in water (i.e., soap water) constitute another useful example of lyotropic LCs. Although the majority of LCs are organic molecules, there exist many LC materials incorporating metals into organic anisotropic molecules [1-3]. These organic-inorganic hybrid LC materials are described as metallomesogens and are recently called metallotropic LCs [4] as distinguished from two main LC classes. In fact, metallomesogens can be classified as either thermotropic or lyotropic LCs depending on their composition and conditions. However, it should be noted that metallomesogens offer a material platform to incorporate magnetic, electronic, optical, redox, and catalytic properties common to inorganic materials into LCs.Although thermotropic LCs have been known to scientists for over 100 years since a discovery by the Austrian botanical physiologist Friedrich Reintizer in 1888, it was only in the late 1960s that they began to be used in display applications. Today, they are best known for their exceptionally successful commercial applications in flat panel display products such as TVs, smart phones, computer displays, and digital projectors. Although today's LC display technology is becoming very advanced, LC materials used in display devices possess the simplest nematic (N) phase and their molecules have been variants on simple rod shapes (Fig. 6.1a). Besides nematic phases, LCs can exhibit other phases: smectic (Sm), columnar (Col), and cubic phases, depending on the orientational or positional orders of their molecules. Nematic phases have only long-range orientational order, smectic mesophases exhibit one-dimensional (1D) positional order and form two-dimensional (2D) layered ...

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Chirality and Macroscopic Polar Order in a Ferroelectric Smectic Liquid-Crystalline Phase Formed by Achiral Polyphilic Bent-Core Molecules

Cited by 61 publications

References 28 publications

Unusual electric-field-induced transformations in the dark conglomerate phase of a bent-core liquid crystal

Unusual electric-field-induced transformations in the dark conglomerate phase of a bent-core liquid crystal

Dark conglomerate phases of bent-core liquid crystals

Electric‐ and Light‐Responsive Bent‐Core Liquid Crystals: From Molecular Architecture and Supramolecular Nanostructures to Applications

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