Temperature-Dependent Thermoelastic Anisotropy of the Phenyl Pyrimidine Liquid Crystal

Ryu, Meguya; Cang, Yu; Wang, Zuyuan; Fytas, George; Morikawa, Junko

doi:10.1021/acs.jpcc.9b04270

Cited by 17 publications

(21 citation statements)

References 33 publications

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“…Generally, in soft matter, the phonon mean free path is usually lower than a few nanometers; this suggests that the phonon mean free path was not underestimated in our simulations. On the other hand, a recent experimental study of a liquid-crystalline molecule revealed low-frequency phonons to have a long mean free path: in the micrometer range, which may be correlated with the finite size effect obtained by our calculations. We attempted to conventionally eliminate the size effect caused by the phonon mean free path, and as a result, the following linear correlation was successfully observed.…”

Section: Resultssupporting

confidence: 85%

“…The thermal diffusivity and TC in LC phases are known to be larger in the direction parallel to the nematic director than perpendicular thereto. Thermal anisotropy has been studied both experimentally − and computationally by using the Gay–Berne model. − In experimental studies, Urbach et al discussed the thermal diffusivity behavior by employing a kinetic model based on an extension of the Eyring theory to anisotropic fluids . On the other hand, Sarman Laaksonen calculated the TC of LC phases of the Gay–Berne fluid and suggested that the anisotropy is derived from molecular movement because the movement along the direction perpendicular to the director is impeded by side-by-side collisions .…”

Section: Introductionmentioning

confidence: 99%

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Atomistic Mechanism of Anisotropic Heat Conduction in the Liquid Crystal 4-Heptyl-4′-cyanobiphenyl: All-Atom Molecular Dynamics

et al. 2019

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All-atom molecular dynamics simulations were performed on 4-heptyl-4′-cyanobiphenyl (7CB) to study the mechanism of heat conduction in this nematic liquid crystal atomistically. To describe 7CB properly, the AMBER-type force field was optimized for the dihedral parameter of biphenyl and the Lennard-Jones parameters. The molecular dynamics calculation using the optimized force field well reproduced the experimental values of the isotropic-nematic phase transition temperature, density, and anisotropy of the thermal conductivity. Furthermore, the contributions of convection, intramolecular interaction, and intermolecular interaction to the thermal conductivity were determined by performing thermal conductivity decomposition analysis. According to the analysis, the contributions of convection, bond stretching, and bond bending interactions were higher in the direction parallel to the nematic director than that perpendicular to the director, which is the origin of the anisotropy in the nematic phase. This result indicates that the anisotropy is caused by well-aligned covalent bonds and high mobility parallel to the director. This quantitative description of the mechanism of heat conduction of 7CB is foreseen to provide new insights toward designing highly thermally conductive liquid-crystalline materials.

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Section: Resultssupporting

confidence: 85%

Section: Introductionmentioning

confidence: 99%

Atomistic Mechanism of Anisotropic Heat Conduction in the Liquid Crystal 4-Heptyl-4′-cyanobiphenyl: All-Atom Molecular Dynamics

et al. 2019

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“…Measurement of the single crystal elastic constants either requires large single crystals or methods applied to polycrystals that can measure elastic properties on length scales below the crystallite diameter. It is well known that single crystal elastic constants can be obtained by frequency-domain Brillouin scattering measurement (see, for example, 27,28 and the references therein). The elastic constants of ceria used in this study were reported in previous work based on time domain Brillouin measurements made on several crystallites with known orientations 17 .…”

Section: Resultsmentioning

confidence: 99%

Imaging grain microstructure in a model ceramic energy material with optically generated coherent acoustic phonons

et al. 2020

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Characterization of microstructure, chemistry and function of energy materials remains a challenge for instrumentation science. This active area of research is making considerable strides with methodologies that employ bright X-rays, electron microscopy, and optical spectroscopy. However, further development of instruments capable of multimodal measurements, is necessary to reveal complex microstructure evolution in realistic environments. In this regard, laser-based instruments have a unique advantage as multiple methodologies are easily combined into a single instrument. A pump-probe method that uses optically generated acoustic phonons is expanding standard optical characterization by providing depth resolved information. Here we report on an extension of this method to image grain microstructure in ceria. Rich information regarding the orientation of individual crystallites is obtained by noting how the polarization of the probe beam influences the detected signal amplitude. When paired with other optical microscopies, this methodology will provide new perspectives for characterization of ceramic materials.

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“…The sound velocity of the Q‐T mode, v Q‐T , first increases, achieves a maximum at around α = 40°–50°, and then decreases, which is a typical feature of v Q‐T in transversely isotropic materials. [ 13,16,24 ] Unlike v Q‐L and v Q‐T , the sound velocity of the P‐T mode ( v P‐T ) shows a weak angular dispersion as v P‐T assumes values almost equal to v P‐T (α = 90°). The robust nature of v P‐T could be a general feature for soft matter, consistent with previous reports on collagen, [ 12 ] liquid crystal, [ 16 ] and spider silk.…”

Section: Resultsmentioning

confidence: 99%

“…It is particularly suitable for determining the elastic properties of transparent samples because the wave vector q of the scattering phonon can be selectively oriented over a wide range of angles. BLS has been utilized to determine the elastic stiffness tensor of many materials, including biofibers, [ 12 ] hybrid stacks of organic and inorganic materials, [ 13 ] molecular liquid crystals, [ 16 ] and crystalline inorganic membranes. [ 17 ]…”

Section: Introductionmentioning

confidence: 99%

Extreme Elasticity Anisotropy in Molecular Glasses

Cang

Wang

Bishop

et al. 2020

Adv Funct Materials

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Glasses are generally assumed to be isotropic and there are no literature reports of elastic anisotropy for molecular glasses. However, as glasses formed by physical vapor deposition can be structurally anisotropic, it is of interest to investigate the elastic anisotropy in these materials. Micro‐Brillouin light spectroscopy is used in several experimental geometries to determine the elastic stiffness tensors of three glass films of itraconazole vapor‐deposited at substrate temperatures (Tsub) of 330, 315, and 290 K, respectively. Significant elastic anisotropy is observed and, in these glasses, the elastic anisotropy shows a strong correlation with the molecular orientation. The out‐of‐plane and in‐plane Young's moduli of the high Tsub (330 K) sample, which features a predominantly vertical molecular orientation, exhibit a high anisotropy ratio of 2.2. The observed elastic anisotropy is much larger than those previously observed in liquid crystals and even many crystalline solids.

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Temperature-Dependent Thermoelastic Anisotropy of the Phenyl Pyrimidine Liquid Crystal

Cited by 17 publications

References 33 publications

Atomistic Mechanism of Anisotropic Heat Conduction in the Liquid Crystal 4-Heptyl-4′-cyanobiphenyl: All-Atom Molecular Dynamics

Atomistic Mechanism of Anisotropic Heat Conduction in the Liquid Crystal 4-Heptyl-4′-cyanobiphenyl: All-Atom Molecular Dynamics

Imaging grain microstructure in a model ceramic energy material with optically generated coherent acoustic phonons

Extreme Elasticity Anisotropy in Molecular Glasses

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