Application of X-ray resonant diffraction to structural studies of liquid crystals

Barois, P.; Gleeson, Helen F.; Huang, C. C.; Pindak, R.

doi:10.1140/epjst/e2012-01628-9

Cited by 15 publications

(10 citation statements)

References 41 publications

(58 reference statements)

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“…Special attention will be paid to resonant X-ray scattering (RXS), toward deducing the chiral structure of certain classes of LCs and the unique information that this method can provide, compared to other techniques. Because several review articles are available, related to chiral LCs [12][13][14][15][16][17][18][19][20] as well as to resonant X-ray of smectic phases made of rod-like [21][22][23][24] and bent-core [23] molecules, we focus here on recent RXS studies of structures without positional order (modulated nematic phases), bent-core modulated smectic phases and on LC materials with chiral morphologies. We conclude with the analysis of the recent progress in chirality control and transfer in LC materials and their nanocomposites.…”

Section: Introductionmentioning

confidence: 99%

Chirality of Liquid Crystals Formed from Achiral Molecules Revealed by Resonant X‐Ray Scattering

et al. 2020

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effect is also responsible for some "biological recognition" processes, including, for example, our physiological response to odor or taste of opposite enantiomeric species. Although chiral interactions have been broadly studied, the mechanism that leads to single handedness in our world is still under discussion. For example, Viedma [1] showed that deracemization in the solid state, coupled with flexibility of transforming one enantiomeric form into another in the liquid state, may lead to chirality synchronization, that is, in a system that starts from a mixture of racemic crystals, a homochiral end state can be obtained. Similarly, crystallization combined with reversible organic reactions, have been reported to transform initially achiral reactants into an enantiopure solid. [2] Whether the spontaneous formation of a homochiral state from a racemic mixture or achiral molecules can be observed in a fluid phase, is still uncertain. In general, in racemic systems lacking long range positional correlations, the chirodiastaltic forces are probably too weak to achieve spontaneous deracemization and (through amplification) enantiomeric excess. Also, in the liquid crystal (LC) state with only orientational order (nematic phase, N), spontaneous deracemization has not been observed so far, since rod-like molecules forming the N phase have freedom to rotate around their long axes, and thus the chiral discrimination effect is reduced. [3] Only few examples have been reported in which chiral discrimination was found to strongly affect nematic phase stability, but not lead to deracemization. [4] There is, however, a particularly interesting group of achiral mesogenic molecules with (constitutional or conformational) bent geometry, for which rotation is strongly hindered and therefore local interactions between neighboring molecules are expected to be much stronger than those in rod-like molecules. In fact, bent molecules have been shown to spontaneously form structurally chiral domains through chirality synchronization in the isotropic liquid [5] and LC [6,7] phases. Thus, further exploration of chirality in soft systems, such as LCs, may have high relevance toward better understanding the origin of life and be transformative for various technologies relying on chirality in soft matter systems. Testing chirality in soft matter systems (liquid crystals and solid crystals) is not always trivial. The most commonly used tools are optical methods focusing on measurements of optical activity (i.e., the ability of matter to rotate the polarization

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Section: Introductionmentioning

confidence: 99%

Chirality of Liquid Crystals Formed from Achiral Molecules Revealed by Resonant X‐Ray Scattering

et al. 2020

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“…Since the period of such superlayer structures, p, can be as short as two layers, the structural study of such phases requires the effective probing of molecular orientation at the nanoscale. This can be achieved using resonant X-ray scattering, a technique sensitive to atomic environment [9][10][11][12][13][14][15][16][17][18][19] that has previously enabled the discovery and definitive characterization of superlayer organization in several SmC* phases and sub-phases, employing the Kedge resonance of atoms incorporated in the liquid crystal molecule [9,11].…”

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confidence: 99%

“…Below 99 • C, the incommensurate peak broadens dramatically and moves to higher q, indicating the presence of short-ranged, Sm2-like helical fluctuations persisting in the Sm3 phase, and disappears at the transition to the Sm4 phase at 83 • C. The Sm4 phase exhibits only the bilayer RSoXS reflection at q B . The RSoXS scattering from a single layer can be analyzed, following Levelut and Pansu, in terms of a monoclinic second-rank tensor with a principal axis tilted from and then azimuthally rotated about the layer normal [10,13,14]. Scattering from a stack of such layers is calculated by summing over the contributions of the individual layers at different z. Resonant scattering peaks from azimuthally periodic arrangements are found at wavevectors along z, q(l, m) = l…”

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confidence: 99%

Chiral Incommensurate Helical Phase in a Smectic of Achiral Bent-Core Mesogens

et al. 2019

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An achiral, bent-core mesogen forms several tilted smectic liquid crystal phases, including a non-polar, achiral de Vries smectic A which transitions to a chiral, ferroelectric state in applied electric fields above a threshold. At lower temperature, a chiral, ferrielectric phase with a periodic, supermolecular modulation of the tilt azimuth, indicated by a Bragg peak in carbon-edge resonant soft X-ray scattering, is observed. The absence of a corresponding resonant Umklapp peak identifies the superlayer structure as a twist-bend-like helix that is only weakly modulated by the smectic layering.

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“…This mode also extends to the whole range of the phase SmC * a . Within that phase, it is accompanied by yet another mode with an amplitude of the same order of magnitude (10)(11)(12)(13)(14)(15)(16)(17)(18)(19)(20), but with a longer relaxation time. It is identied as a phase-type Goldstone mode describing the dynamics of the ferroelectric phase SmC*.…”

Section: Results Obtained By Dielectric Spectroscopymentioning

confidence: 99%

“…According to the theoretical predictions of the generalised Landau model, 15 the relaxation time s of the phase-type Goldstone mode is proportional to the square of the helix pitch p. The expected pitch in the helical structure of the SmC * a phase, expressed in terms of the number of smectic layers with a thickness of about 4 nm each, ranges from a few to several dozens. [16][17][18] This means that the quantity p in that phase should fall within the range of 10-100 nm. On the other hand, the average values of the parameter p in the SmC* phases are comprised within the range of several hundred to several thousand nm and are 10 to 100 times longer.…”

Section: Results Obtained By Dielectric Spectroscopymentioning

confidence: 99%

Experimental evidence of soft mode in the smectic C*α phase of chiral ferroelectric liquid crystals

et al. 2014

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Dielectric properties of chiral smectic liquid crystals characterised by the occurrence of the C(α)(*) phase were investigated in the frequency range 10 Hz-1 MHz. In the range of existence of this phase the observed relaxation spectrum is composed of two kinds of mode, and not of a single one, as commonly thought. Phase modes of the Goldstone type coexist in it with an amplitude type soft mode. The share of the soft mode in the global value of electric permittivity ε can be dominant and attain 90%. A possible explanation for that effect is sought in the similarity to chiral phases of the de Vries type.

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Application of X-ray resonant diffraction to structural studies of liquid crystals

Cited by 15 publications

References 41 publications

Chirality of Liquid Crystals Formed from Achiral Molecules Revealed by Resonant X‐Ray Scattering

Chirality of Liquid Crystals Formed from Achiral Molecules Revealed by Resonant X‐Ray Scattering

Chiral Incommensurate Helical Phase in a Smectic of Achiral Bent-Core Mesogens

Experimental evidence of soft mode in the smectic C*α phase of chiral ferroelectric liquid crystals

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