Colloidal liquid crystals in rectangular confinement: theory and experiment

Lewis, Alexander H.; Gârlea, Ioana C.; Alvarado, José; Dammone, Oliver; Howell, Peter; Majumdar, Apala; Mulder, Bela M.; Lettinga, M. P.; Koenderink, Gijsje H.; Aarts, Dirk G. A. L.

doi:10.1039/c4sm01123f

Cited by 70 publications

(136 citation statements)

References 41 publications

(89 reference statements)

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“…This transition survives even in the extreme confinement limit 0  H ; therefore, it is interpreted as the isotropic-nematic transition of two-dimensional (2D) hard rods [24,25]. Along these lines, both experimental and theoretical studies have been devoted to the capillary nematisation and the surface ordering in strongly confined lyotropic and thermotropic liquid crystals [10,[26][27][28][29][30]. Even a second order isotropic-nematic phase transition can be observed in extremely confined semiflexible polymer solutions [31].…”

Section: Introductionmentioning

confidence: 99%

Ordering transitions of weakly anisotropic hard rods in narrow slitlike pores

et al. 2018

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The effect of strong confinement on the positional and orientational ordering is examined in a system of hard rectangular rods with length L and diameter D (L>D) using the Parsons-Lee modification of the second virial density-functional theory. The rods are nonmesogenic (L/D<3) and confined between two parallel hard walls, where the width of the pore (H) is chosen in such a way that both planar (particle's long axis parallel to the walls) and homeotropic (particle's long axis perpendicular to the walls) orderings are possible and a maximum of two layers are allowed to form in the pore. In the extreme confinement limit of D H 2  , where only one layer structures appear, we observe a structural transition from a planar to a homeotropic fluid layer with increasing density, which becomes sharper as L H. In wider pores (2D

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Section: Introductionmentioning

confidence: 99%

Ordering transitions of weakly anisotropic hard rods in narrow slitlike pores

et al. 2018

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“…in microfluidics channels, adds elastic stress to the material. A wall often forces a certain orientation of the particles close to it (anchoring), and when a liquid crystal is confined between two or more such walls, anchoring and distortion energies must compete to determine the configuration of the director field, which is often different from that seen in bulk [2]. It has previously been shown for this particular system that anchoring is very strong and, depending on the opening angle of the wedge, the director field will either form a splay deformation or a combination of splay and bend deformations [1].…”

Section: Application To Experimental Datamentioning

confidence: 99%

“…recent work by [1][2][3][4][5][6]. For colloidal liquid crystals, the effects of confinement may even be more pronounced with confinement down to the particle level.…”

Section: Introductionmentioning

confidence: 96%

Direct calculation of distortion energies in colloidal liquid crystals from single-particle data

et al. 2015

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We report a method to calculate distortion energies of a colloidal liquid crystal from single-particle data via a triangulation of the particle positions followed by a linear interpolation of the particle orientations. Our method provides local information on the strength and type of distortions present in a liquid crystal. We validate our method by applying it to artificially generated data and show that the results are in good agreement with exact calculations of the distortion energy. We further illustrate our method by using it on laser scanning confocal microscopy images of the nematic phase of fd-virus particles in wedge-shaped microfluidics channels.

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“…We employ the popular Rapini–Papoular surface energy , which in normalized form reads as

E_{S} = \frac{1}{2} \int_{\partial Ω} α {prefixcos}^{2} false(θ - φ false) d σ,

where

\partial Ω

consists of two concentric circles, with radii

r = ρ

and

r = 1

, and dσ is arc‐length element along

\partial Ω

. The dimensionless anchoring strength

α : = R_{outer} / ξ

is the ratio of the outer radius to the extrapolation length ξ, , and the three key modeling parameters are then δ, ρ, and α. The extrapolation length,

ξ = K_{3} / W

, is the ratio of the bending elastic constant to the physical surface anchoring strength parameter W , such that

W \to \infty

describes the strong anchoring regime .…”

Section: Theory and Modelingmentioning

confidence: 99%

Nematic Equilibria on a Two‐Dimensional Annulus

et al. 2017

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We study planar nematic equilibria on a two-dimensional annulus with strong and weak tangent anchoring, in the Oseen-Frank theoretical framework. We analyze a radially invariant defect-free state and compute analytic stability criteria for this state in terms of the elastic anisotropy, annular aspect ratio, and anchoring strength. In the strong anchoring case, we define and characterize a new spiral-like equilibrium which emerges as the defectfree state loses stability. In the weak anchoring case, we compute stability diagrams that quantify the response of the defect-free state to radial and azimuthal perturbations. We study sector equilibria on sectors of an annulus, including the effects of weak anchoring and elastic anisotropy, giving novel insights into the correlation between preferred numbers of boundary defects and the geometry. We numerically demonstrate that these sector configurations can approximate experimentally observed equilibria with boundary defects.

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Colloidal liquid crystals in rectangular confinement: theory and experiment

Cited by 70 publications

References 41 publications

Ordering transitions of weakly anisotropic hard rods in narrow slitlike pores

Ordering transitions of weakly anisotropic hard rods in narrow slitlike pores

Direct calculation of distortion energies in colloidal liquid crystals from single-particle data

Nematic Equilibria on a Two‐Dimensional Annulus

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