Direct observation of liquid crystals using cryo‐TEM: Specimen preparation and low‐dose imaging

Gao, Min; Kim, Young-Ki; Zhang, Cuiyu; Borshch, Volodymyr; Zhou, Shuang; Park, Heung‐Shik; Jákli, Antal; Lavrentovich, Oleg D.; Tamba, Maria-Gabriela; Kohlmeier, Alexandra; Mehl, Georg H.; Weißflog, W.; Studer, Daniel; Zuber, Benoît; Gnägi, Helmut; Lin, Fang

doi:10.1002/jemt.22397

Cited by 89 publications

(93 citation statements)

References 70 publications

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“…Notably, chiral domains in the nematic phase of achiral compounds exhibiting dimerisation through hydrogen bonding were reported more than 15 years ago 19 ; however, such domains were found to exhibit macroscopic twist deformation of the director in the optical regime. Lastly, although the twist-bend model has been proposed 8,9,11,12,16,20 for the consistent interpretation of various experimental observations on the dimer N X phase, there is, to our knowledge, no direct identification of the heliconical structure and, furthermore, there are indications 21,22 that the dominant molecular arrangement in the N X phase could differ from that of the twist-bend model.…”

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confidence: 83%

On the structure of the Nx phase of symmetric dimers: inferences from NMR

et al. 2015

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NMR measurements on a selectively deuterated liquid crystal dimer CB-C9-CB, exhibiting two nematic phases, show that the molecules in the lower temperature nematic phase, N(X), experience a chiral environment and are ordered about a uniformly oriented director throughout the macroscopic sample. The results are contrasted with previous interpretations that suggested a twist-bend spatial variation of the director. A structural picture is proposed wherein the molecules are packed into highly correlated chiral assemblies.

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confidence: 83%

On the structure of the Nx phase of symmetric dimers: inferences from NMR

et al. 2015

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“…Previous studies on other thermotropic bent-core LC films carried out with this instrument demonstrated the possibility to visualise smectic layers with resolution better than 0.7 nm. [22,[24][25][26] The LC samples were dissolved in chloroform, and the solution was dispersed on a TEM grid coated with plasma-treated continuous carbon film. After evaporation of the chloroform, the thickness of the LC films was between 50 and 100 nm.…”

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Nanoscale structures of polarisation-modulated bent-core materials in thin films

et al. 2015

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We present small angle X-ray and cryogenic transmission electron microscopy (cryo-TEM) studies of three nitrosubstituted (n-OPIMB-NO 2 , n = 7, 9 and16) bent-core liquid crystals (LCs) that form peculiar optical patterns known as B7 textures. Small angle X-ray scattering studies show two periodicities between a~3.4-4.7 nm and b X~9 -16 nm. Cryo-TEM images of about 100 nm thick films do not show the a-periodicity, but only periodicities b T that are about 1 nm smaller than b X measured in bulk by X-ray. Additionally, an intensity modulation with a period c~100-200 nm is observed. These observations can be explained by a B1-type structure, where there are half-layer step discontinuities at the boundaries of the splay domains, and where the molecules are everywhere normal to the substrate.

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“…The manipulation of these nanometer-size molecules into coherent, centimeter-scale structures is now routine. Although we have become adept at deducing textures indirectly through optical microscopies (1)(2)(3)(4)(5), probing the molecular-scale organization requires either a glassy material or rapid cooling of samples, providing metastable states that can be directly visualized through scanning electron microscopy (SEM), transmission electron microscopy (TEM), and atomic force microscopy (AFM) (6)(7)(8). Although these techniques are effective to study a variety of more complex LC phases, including smectic LCs (6,7,9), cholesteric and blue phases (10), and biological LC polymers (11,12), nonglassy, low molecular weight nematic LCs (NLCs) reorient during fast freezing.…”

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Direct mapping of local director field of nematic liquid crystals at the nanoscale

Xia

Serra

Kamien

et al. 2015

Proc. Natl. Acad. Sci. U.S.A.

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Liquid crystals (LCs), owing to their anisotropy in molecular ordering, are of wide interest in both the display industry and soft matter as a route to more sophisticated optical objects, to direct phase separation, and to facilitate colloidal assemblies. However, it remains challenging to directly probe the molecular-scale organization of nonglassy nematic LC molecules without altering the LC directors. We design and synthesize a new type of nematic liquid crystal monomer (LCM) system with strong dipole-dipole interactions, resulting in a stable nematic phase and strong homeotropic anchoring on silica surfaces. Upon photopolymerization, the director field can be faithfully "locked," allowing for direct visualization of the LC director field and defect structures by scanning electron microscopy (SEM) in real space with 100-nm resolution. Using this technique, we study the nematic textures in more complex LC/colloidal systems and calculate the extrapolation length of the LCM.nematic liquid crystal polymers | dipole-dipole interactions | topological defects | photo-cross-linking | nanoscale imaging

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Direct observation of liquid crystals using cryo‐TEM: Specimen preparation and low‐dose imaging

Cited by 89 publications

References 70 publications

On the structure of the Nx phase of symmetric dimers: inferences from NMR

On the structure of the Nx phase of symmetric dimers: inferences from NMR

Nanoscale structures of polarisation-modulated bent-core materials in thin films

Direct mapping of local director field of nematic liquid crystals at the nanoscale

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