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Liquid Crystals Reviews Volume 8, 2020 - Issue 1
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Effect of phase transitions on liquid crystal colloids: a short review

Kottoli Poyil Zuhaila J. Stefan Institute, Ljubljana, Slovenia;d School of Physics, University of Hyderabad, Hyderabad, IndiaView further author information
,
Matjaž Humara J. Stefan Institute, Ljubljana, Slovenia;b Department of Condensed Matter Physics, Faculty of Mathematics and Physics, University of Ljubljana, Ljubljana, Slovenia;c CENN Nanocenter, Ljubljana, SloveniaORCID Iconhttps://orcid.org/0000-0003-3338-6723View further author information
ORCID Icon &
Surajit Dharad School of Physics, University of Hyderabad, Hyderabad, IndiaCorrespondence[email protected]
[email protected]
ORCID Iconhttps://orcid.org/0000-0003-3144-0300View further author information
ORCID Icon
Pages 44-57 | Received 08 Jan 2021, Accepted 13 Mar 2021, Published online: 02 Apr 2021

References

  • de Gennes PG, Prost J. The physics of liquid crystals. 1995. (International Series of Monographs on Physics).
  • Chandrasekhar S. Liquid crystals. 2nd ed. Cambridge (UK): Cambridge University Press; 1992.
  • Bahr C, Kitzerow HS. Chirality in liquid crystals. Heidelberg: Springer; 2001.
  • Poulin P, Stark H, Lubensky TC, et al. Novel colloidal interactions in anisotropic fluids. Science. 1997;275:1770–1773.
  • Muševič I. Liquid crystal colloids. 2017. (Springer International Publishing AG).
  • Smalyukh II. Liquid crystal colloids. Annu Rev Condens Matter Phys. 2018;9:207–216.
  • Muševič I, Škarabot M, Tkalec U, et al. Two-dimensional nematic colloidal crystals self-assembled by topological defects. Science. 2006;313:954–958.
  • Stark H. Physics of colloidal dispersions in nematic liquid crystals. Phys Rep. 2001;351:387–474.
  • Trivedi RP, Engstrom D, Smalyukh II. Optical manipulation of colloids and defect structures in anisotropic liquid crystal fluids. J Opt. 2011;13:044001.
  • Kuksenok OV, Ruhwandl RW, Shiyanovskii SV, et al. Director structure around a colloid particle suspended in a nematic liquid crystal. Phys Rev E. 1996;54:5198.
  • Poulin P, Cabuil V, Weitz DA. Direct measurement of colloidal forces in an anisotropic solvent. Phys Rev Lett. 1997;79:4862.
  • Mozaffari MR, Babadi M, Fukuda JI, et al. Interaction of spherical colloidal particles in nematic media with degenerate planar anchoring. Soft Matter. 2011;7:1107–1113.
  • Eskandari Z, Silvestre NM. Bonded boojum-colloids in nematic liquid crystals. Langmuir. 2013;29:10360–10367.
  • Liu Q, Senyuk B, Tasinkevych M, et al. Nematic liquid crystal boojums with handles on colloidal handlebodies. Proc Natl Acad Sci USA. 2013;110:9231–9236.
  • Tasinkevych M, Silvestre NM. Liquid crystal boojum-colloids. New J Phys. 2012;14:073030.
  • Smalyukh II, Lavrentovich OD, Kuzmin AN, et al. Elasticity-mediated self-organization and colloidal interactions of solid spheres with tangential anchoring in a nematic liquid crystal. Phys Rev Lett. 2005;95:157801.
  • Loudet JC, Poulin P, Barois P. Edge dislocations of colloidal chains suspended in a nematic liquid crystal. Europhys Lett. 2001;54:175.
  • Nazarenko VG, Nych AB, Lev BI. Crystal structure in nematic emulsion. Phys Rev Lett. 2001;87:075504.
  • Gu Y, Abbott NL. Observation of Saturn-ring defects around solid microspheres in nematic liquid crystals. Phys Rev Lett. 2000;85:4719.
  • Lubensky TC, Pettey D, Currier N, et al. Topological defects and interactions in nematic emulsions. Phys Rev E. 1998;57:610.
  • Petrov PG, Terentjev EM. Formation of cellular solid in liquid crystal colloids. Langmuir. 2001;17:2942–2949.
  • Yada M, Yamamoto J, Yokoyama H. Direct observation of anisotropic interparticle forces in nematic colloids with optical tweezers. Phys Rev Lett. 2004;92:185501.
  • Pawsey AC, Clegg PS. Colloidal particles in blue phase liquid crystals. Soft Matter. 2015;11:3304.
  • Nych A, Ognysta U, Škarabot M, et al. Assembly and control of 3D nematic dipolar colloidal crystals. Nat Commun. 2015;4:1289.
  • Rasna MV, Zuhail KP, Ramudu UV, et al. Orientation, interaction and laser assisted self-assembly of organic single crystal micro-sheets in nematic liquid crystal. Soft Matter. 2015;11:7674.
  • Ognysta U, Nych A, Nazarenko V, et al. Design of 2D binary colloidal crystals in a nematic liquid crystal. Langmuir. 2009;25:12092–12100.
  • Sahu DK, Anjali TG, Basavraj MG, et al. Orientation, elastic interaction and magnetic response of asymmetric colloids in a nematic liquid crystal. Sci Rep. 2019;9:1–10.
  • Senyuk B, Liu Q, Bililign E, et al. Geometry-guided colloidal interactions and self-tiling of elastic dipoles formed by truncated pyramid particles in liquid crystals. Phys Rev E. 2015;91:040501(R).
  • Rasi M, Pujala RK, Dhara S. Colloidal analogues of polymer chains, ribbons and 2D crystals employing orientations and interactions of nano-rods dispersed in a nematic liquid crystal. Sci Rep. 2019;9:1–11.
  • Sudhakaran DV, Pujala RK, Dhara S. Orientation dependent interaction and self-assembly of cubic magnetic colloids in a nematic liquid crystal. Adv Opt Mater. 2020;8:1901585.
  • Pishnyak OP, Tang S, Kelly JR, et al. Levitation, lift, and bidirectional motion of colloidal particles in an electrically driven nematic liquid crystal. Phys Rev Lett. 2007;99:127802.
  • Muševič I, Škarabot M, Babič D, et al. Laser trapping of small colloidal particles in a nematic liquid crystal: clouds and ghosts. Phys Rev Lett. 2004;93:187801.
  • Škarabot M, Ravnik M, Babič D, et al. Laser trapping of low refractive index colloids in a nematic liquid crystal. Phys Rev E. 2006;73:021705.
  • Škarabot M, Lokar Z, Muševič I. Transport of particles by a thermally induced gradient of the order parameter in nematic liquid crystals. Phys Rev E. 2013;87:062501.
  • Zuhail KP, Sathyanarayana P, Seč D, et al. Topological defect transformation and structural transition of two-dimensional colloidal crystals across the nematic to smectic-A phase transition. Phys Rev E. 2015;91:030501.
  • Ravnik M, Žumer S. Landau-de gennes modelling of nematic liquid crystal colloids. Liq Cryst. 2009;36:1201–1214.
  • Zuhail KP, Čopar S, Muševič I, et al. Spherical microparticles with Saturn ring defects and their self-assembly across the nematic to smectic-A phase transition. Phys Rev E. 2015;92:052501.
  • Mondain-Monval O, Dedieu JC, Gulik-Krzywicki T, et al. Weak surface energy in nematic dispersions: Saturn ring defects and quadrupolar interactions. Eur Phys J B. 1999;12:167–170.
  • Ognysta U, Nych A, Nazarenko V, et al. 2D interactions and binary crystals of dipolar and quadrupolar nematic colloids. Phys Rev Lett. 2008;100:217803.
  • Puschel-Schlotthauer S, Meiwes Turrion V, Hall CK, et al. The impact of colloidal surface-anchoring on the smectic A phase. Langmuir. 2017;33:2222–2234.
  • Blanc C, Kleman M. The confinement of smectics with a strong anchoring. Euro Phys J E. 2001;4:241–251.
  • Zuhail KP, Dhara S. Temperature dependence of equilibrium separation and lattice parameters of nematic boojum-colloids. Appl Phys Lett. 2015;106:211901.
  • Poulin P, Cabuil V, Weitz DA. Direct measurement of colloidal forces in an anisotropic solvent. Phys Rev Lett. 1997;79:4862.
  • Fukuda JI, Yokoyama H. Separation-independent attractive force between like particles mediated by nematic-liquid-crystal distortions. Phys Rev Lett. 2005;94:148301.
  • Tkalec U, Ravnik M, Zumer S, et al. Vortexlike topological defects in nematic colloids: chiral colloidal dimers and 2D crystals. Phys Rev Lett. 2009;103:127801.
  • Tkalec U, Muševič I. Topology of nematic liquid crystal colloids confined to two dimensions. Soft Matter. 2013;9:8140–8150.
  • Zuhail KP, Dhara S. Effect of temperature and electric field on 2D nematic colloidal crystals stabilised by vortex-like topological defects. Soft Matter. 2016;12:6812–6816.
  • Stannarius R, Harth K. Defect interactions in anisotropic two-dimensional fluids. Phys Rev Lett. 2016;117:157801.
  • Stannarius R, Harth K. Inclusions in freely suspended smectic films. Liquid crystals with nano and microparticles. In: Lagerwall JP, Giusy Scalia, editors. World Scientific. Luxembourg; Vol-I, 2017. p. 361–414.
  • Dolganov PV, Cluzeau P, Dolganov VK. Interaction and self-organization of inclusions in two-dimensional free-standing smectic films. Liq Cryst Rev. 2019;7:1–29.
  • Dolganov PV, Dolganov VK. Director configuration and self-organization of inclusions in two-dimensional smectic membranes. Phys Rev E. 2006;73:041706.
  • Patricio P, Tasinkevych M, Telo da Gama MM. Colloidal dipolar interactions in 2D smectic-C films. Eur Phys J E. 2002;7:117–120.
  • Gim MJ, Beller DA, Yoon DK. Morphogenesis of liquid crystal topological defects during the nematic-smectic A phase transition. Nat Commun. 2016;8:15453.
  • Turner MS, Sens P, Pincus P. Particulate inclusions in a lamellar phase. Phys Rev E. 1997;55:4394.
  • Santangelo CD, Kamien RD. Bogomol'nyi, prasad, and sommerfield configurations in smectics. Phys Rev Lett. 2003;91:045506.
  • Tovkach OM, Fukuda JI, Lev BI. Peculiarity of the interaction of small particles in smectic liquid crystals. Phys Rev E. 2013;88:052502.
  • Schiller P. Indirect interaction of colloidal particles adsorbed on smectic films. Phys Rev E. 2000;62:918.
  • Turner MS, Sens P. Interactions between particulate inclusions in a smectic-A liquid crystal. Phys Rev E. 1997;55:R1275.
  • Rasi M, Zuhail KP, Roy A, et al. N- sm A- sm C phase transitions probed by a pair of elastically bound colloids. Phys Rev E. 2018;97:032702.
  • Bohley C, Stannarius R. Energetics of 2D colloids in free-standing smectic-C films. Eur Phys J E. 2006;20:299–308.
  • Silvestre NM, Patricio P. Elliptical soft colloids in smectic-C films. Phys Rev E. 2006;74:021706.
  • Dolganov PV, Nguyen HT, Joly G, et al. Shape of nematic droplets in smectic membranes. Euro Phys Lett. 2007;78:66001.
  • Gvozdovskyy I, Jampani VS, Škarabot M, et al. Light-induced rewiring and winding of Saturn ring defects in photosensitive chiral nematic colloids. Eur Phys J E. 2013;36:97.
  • Lintuvuori JS, Stratford K, Cates ME, et al. Colloids in cholesterics: size-dependent defects and non-Stokesian microrheology. Phys Rev Lett. 2010;105:178302.
  • Lintuvuori JS, Marenduzzo D, Stratford K, et al. Colloids in liquid crystals: a lattice boltzmann study. J Mater Chem. 2010;20:10547–10552.
  • Senyuk B, Lavrentovich OD, Smith CJ, et al. Rotation of solid spherical particles moving through a cholesteric liquid crystal. In 22nd International Liquid Crystal Conference, Jeju, Korea, 2008 (Genicom Co., Ltd., Daejeon, 2008).
  • Jampani VS, Škarabot M, Ravnik M, et al. Colloidal entanglement in highly twisted chiral nematic colloids: twisted loops, hopf links, and trefoil knots. Phys Rev E. 2011;84:031703.
  • Senyuk B, Puls O, Tovkach M, et al. Hexadecapolar colloids. Nat Commun. 2016;7:1–7.
  • Senyuk B, Liu Q, He S, et al. Topological colloids. Nature. 2013;493:200–205.
  • Yuan Y, Liu Q, Senyuk B, et al. Elastic colloidal monopoles and reconfigurable self-assembly in liquid crystals. Nature. 2019;570:214–218.

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