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1. Chromonic liquid crystals and packing configurations of bacteriophage viruses

   https://doi.org/10.1098/rsta.2020.0111  

   Hiltner, Lindsey ; Carme Calderer, M. ; Arsuaga, Javier ; Vázquez, Mariel ( July 2021 , Philosophical Transactions of the Royal Society A: Mathematical, Physical and Engineering Sciences)

   null (Ed.)

   We study equilibrium configurations of hexagonal columnar liquid crystals in the context of characterizing packing structures of bacteriophage viruses in a protein capsid. These are viruses that infect bacteria and are currently the focus of intense research efforts, with the goal of finding new therapies for bacteria-resistant antibiotics. The energy that we propose consists of the Oseen–Frank free energy of nematic liquid crystals that penalizes bending of the columnar directions, in addition to the cross-sectional elastic energy accounting for distortions of the transverse hexagonal structure; we also consider the isotropic contribution of the core and the energy of the unknown interface between the outer ordered region of the capsid and the inner disordered core. The problem becomes of free boundary type, with constraints. We show that the concentric, azimuthal, spool-like configuration is the absolute minimizer. Moreover, we present examples of toroidal structures formed by DNA in free solution and compare them with the analogous ones occurring in experiments with other types of lyotropic liquid crystals, such as food dyes and additives. This article is part of the theme issue ‘Topics in mathematical design of complex materials’. 

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2. Azimuthal Anchoring Strength in Photopatterned Alignment of a Nematic

   https://doi.org/10.3390/cryst11060675  

   Padmini, H. Nilanthi ; Rajabi, Mojtaba ; Shiyanovskii, Sergij V. ; Lavrentovich, Oleg D. ( June 2021 , Crystals)

   null (Ed.)

   Spatially-varying director fields have become an important part of research and development in liquid crystals. Characterization of the anchoring strength associated with a spatially-varying director is difficult, since the methods developed for a uniform alignment are seldom applicable. Here we characterize the strength of azimuthal surface anchoring produced by the photoalignment technique based on plasmonic metamsaks. The measurements used photopatterned arrays of topological point defects of strength +1 and −1 in thin layers of a nematic liquid crystal. The integer-strength defects split into pairs of half-integer defects with lower elastic energy. The separation distance between the split pair is limited by the azimuthal surface anchoring, which allows one to determine the strength of the latter. The strength of the azimuthal anchoring is proportional to the UV exposure time during the photoalignment of the azobenzene layer. 

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3. Nematic colloids at liquid crystal–air interfaces via photopolymerization

   https://doi.org/10.1039/d0sm01311k  

   Wei, Xiaoshuang ; Sbalbi, Nicholas ; Bradley, Laura C. ( October 2020 , Soft Matter)

   null (Ed.)

   We demonstrate the preparation of colloidal crystals at nematic liquid crystal–air interfaces by simultaneous photopolymerization and assembly. Polymer colloids are produced by polymerization-induced phase separation of 2-hydroxyethyl methacrylate in the non-reactive liquid crystal (LC) 4-cyano-4′-pentylbiphenyl (5CB) using an open-cell setup. Colloids adsorbed to the nematic 5CB–air interface form non-close-packed hexagonal crystals that cover the entire interface area. We examine the mechanism of growth and assembly for the preparation of LC-templated interfacial colloidal superstructures. 

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4. Hard superellipse phases: particle shape anisotropy & curvature

   https://doi.org/10.1039/D1SM01523K  

   Torres-Díaz, Isaac ; Hendley, Rachel S. ; Mishra, Akhilesh ; Yeh, Alex J. ; Bevan, Michael A. ( February 2022 , Soft Matter)

   We report computer simulations of two-dimensional convex hard superellipse particle phases vs. particle shape parameters including aspect ratio, corner curvature, and sidewall curvature. Shapes investigated include disks, ellipses, squares, rectangles, and rhombuses, as well as shapes with non-uniform curvature including rounded squares, rounded rectangles, and rounded rhombuses. Using measures of orientational order, order parameters, and a novel stretched bond orientational order parameter, we systematically identify particle shape properties that determine liquid crystal and crystalline phases including their coarse boundaries and symmetry. We observe phases including isotropic, nematic, tetratic, plastic crystals, square crystals, and hexagonal crystals (including stretched variants). Our results catalog known benchmark shapes, but include new shapes that also interpolate between known shapes. Our results indicate design rules for particle shapes that determine two-dimensional liquid, liquid crystalline, and crystalline microstructures that can be realized via particle assembly. 

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5. Hard convex lens-shaped particles: metastable, glassy and jammed states

   https://doi.org/10.1039/c8sm01519h  

   Cinacchi, Giorgio ; Torquato, Salvatore ( October 2018 , Soft Matter)

   We generate and study dense positionally and/or orientationally disordered, including jammed, monodisperse packings of hard convex lens-shaped particles (lenses). Relatively dense isotropic fluid configurations of lenses of various aspect ratios are slowly compressed via a Monte Carlo method based procedure. Under this compression protocol, while ‘flat’ lenses form a nematic fluid phase (where particles are positionally disordered but orientationally ordered) and ‘globular’ lenses form a plastic solid phase (where particles are positionally ordered but orientationally disordered), ‘intermediate’, neither ‘flat’ nor ‘globular’, lenses do not form either mesophase. In general, a crystal solid phase (where particles are both positionally and orientationally ordered) does not spontaneously form during lengthy numerical simulation runs. In correspondence to those volume fractions at which a transition to the crystal solid phase would occur in equilibrium, a ‘downturn’ is observed in the inverse compressibility factor versus volume fraction curve beyond which this curve behaves essentially linearly. This allows us to estimate the volume fraction at jamming of the dense non-crystalline packings so generated. These packings are nematic for ‘flat’ lenses and plastic for ‘globular’ lenses, while they are robustly isotropic for ‘intermediate’ lenses, as confirmed by the calculation of the τ order metric, among other quantities. The structure factors S ( k ) of the corresponding jammed states tend to zero as the wavenumber k goes to zero, indicating they are effectively hyperuniform ( i.e. , their infinite-wavelength density fluctuations are anomalously suppressed). Among all possible lens shapes, ‘intermediate’ lenses with aspect ratio around 2/3 are special because they are those that reach the highest volume fractions at jamming while being positionally and orientationally disordered and these volume fractions are as high as those reached by nematic jammed states of ‘flat’ lenses and plastic jammed states of ‘globular’ lenses. All of their attributes, taken together, make such ‘intermediate’ lens packings particularly good glass-forming materials. 

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