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Liquid Crystals Volume 45, 2018 - Issue 13-15: A Festschrift in honour of Professor Claudio Zannoni; Guest Editors: Roberto Berardi, Luca Muccioli and Paolo Pasini
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Invited Article

Some reflections on defects in liquid crystals: from Amerio to Zannoni and beyond

Timothy J. SluckinMathematical Sciences, University of Southampton, Southampton, UK;Dipartimento di Fisica, Politecnico di Milano, Milano, ItalyCorrespondence[email protected]
ORCID Iconhttp://orcid.org/0000-0002-9163-0061
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Pages 1894-1912 | Received 17 Jun 2018, Published online: 31 Jul 2018

References

  • Sluckin T. Professor Sir Charles Frank (1911–1998): historical perspectives on the development of liquid crystal continuum theory. Liquid Crystals Today. 1998;8(3):1–5.
  • Sluckin TJ, Dunmur DA, Stegemeyer H. Crystals that flow: classic papers from the history of liquid crystals.London: Taylor & Francis; 2004.
  • Dunmur D, Sluckin T. Soap, science, and flat-screen TVs: a history of liquid crystals. Oxford: Oxford University Press; 2011.
  • Friedel G. Les états mésomorphes de la matière. In: Annales de Physique. 1922. Vol. 9:273–474; this famous article is partly translated into English in ref.[[2]].
  • Volovik G, Mineev V. Line and point singularities in superfluid he-3. Jetp. Lett. 1976;24:561–563.
  • Kléman M, Michel L, Toulouse G. Classification of topologically stable defects in ordered media. Journal De Physique Letters. 1977;38(10):195–197.
  • Mermin N. The homotopy groups of condensed matter physics. J Math Phys. 1978;19(6):1457–1462.
  • Mermin ND. The topological theory of defects in ordered media. Rev Mod Phys. 1979;51:591–648.
  • Kléman M. Defects in liquid crystals. Rep Prog Phys. 1989;52:555–654.
  • Betti E. Sopra gli spazi di un numero qualunque di dimensioni. Annali Di Matematica Pura Ed Applicata (1867–1897). 1870;4(1):140–158.
  • Stillwell J. Mathematics and its history.3rd edition,New York Springer;2010
  • Edelsbrunner H, Letscher D, Zomorodian A, Topological persistence and simplification, in: Foundations of Computer Science, 2000. Proceedings. 41st Annual Symposium on, IEEE, 2000, pp. 454–463.
  • Knoll PM, Kelker H. Otto Lehmann: researcher of the liquid crystals. BoD–Books on Demand; 2012.
  • Lagerwall ST. On some important chapters in the history of liquid crystals. Liq Cryst. 2013;40(12):1698–1729.
  • Mitov M. Liquid-crystal science from 1888 to 1922: building a revolution. ChemPhysChem. 2014;15(7):1245–1250.
  • Lehmann O. Flüssige Kristalle. Leipzig:Wilhelm Engelmann. 1904.
  • Prinsen P, Van Der Schoot P. Shape and director-field transformation of tactoids. Physical Review E. 2003;68(2):021701.
  • Prinsen P, Van Der Schoot P. Continuous director-field transformation of nematic tactoids. Eur Phys J E. 2004;13(1):35–41.
  • Zhang C, Acharya A, Walkington NJ, et al. Computational modelling of tactoid dynamics in chromonic liquid crystals. Liq Cryst 2018;45:1084-1100.
  • Machon T, Alexander GP. Umbilic lines in orientational order. Physical Review X. 2016;6(1):011033.
  • Viola CM, La legge degli indici razionali semplici e i cristalli liquidi, Processi verbali di Società Toscana di Scienze naturali (1901) 178–193 Read at meeting of 17 March 1901.
  • Oseen CW. Die anisotropen Flüssigkeiten: tatsachen und Theorien. Gebrüder Borntraeger:  Berlin; 1929.
  • Guerraggio A, Paoloni G. Vito Volterra. Franco Muzzio, Padova, 2008 (in Italian).
  • Goodstein JR. The Volterra Chronicles: the Life and Times of an Extraordinary Mathematician, 1860–1940. American Mathematical Soc.; 2007.
  • Weingarten J. Sulle superficie di discontinuá nella teoria della elasticità dei corpi solidi, Rendiconti della R. Accademia Lincei. 1901;10:57–60.
  • Lamb H. Hydrodynamics. 2nd. Cambridge:Cambridge University Press; 1895. (An original volume under the title of A treatise on the mathematical theory of the motion of fluids appeared in 1879, while another edition of Hydrodynamics appeared in 1906).
  • Volterra V. Sull’equilibrio dei corpi elastici più volte connessi. Rendiconti Della R Accademia Lincei. 1905;14:193–202. See also other articles in the original series on distorsioni on pp 127–137, pp 350–6, pp 431–8, pp 641–54 and vol 14 pp 329–42.
  • Volterra V. Sur l’équilibre des corps élastiques multiplement connexes. Annales De L’école Normale Supérieure. 1907;24:401–518.
  • Volterra V, Volterra E. Sur les distorsions des corps élastiques (théorie et applications). Paris: Gauthier-Villars; 1960. ( (The first three chapters of this book were written by Volterra père in 1938, and the rest was completed much later by Volterra fils.)).
  • Love AEH. A treatise on the mathematical theory of elasticity. 1st. Cambridge: Cambridge University Press; 1892. (The 4th edition of Love, published in 1927, is the one which transmuted Volterra’s distorsioni into “dislocations”).
  • Bragg WH, Bragg WL. The reflection of X-rays by crystals. Proc Roy Soc. 1913;88:428–438.
  • Knipping P. Zehn Jahre Röntgenstrahlinterferenzen. Die Naturwissenschaften. 1922;10:366–369.
  • Brock WH, Knight DM. The atomic debates:” memorable and interesting evenings in the life of the chemical society”. Isis. 1965;56(1):5–25.
  • Frenkel J. Zur Theorie der Elastizitätsgrenze und der Festigkeit kristallinischer Körper. Zeitschrift Für Physik. 1926;37:572–609.
  • Dehlinger U. Zur Theorie der Rekristallisation reiner Metalle. Ann Phys. 1929;2:749–793.
  • Taylor GI. The mechanism of plastic deformation of crystals. Part I. Theoretical. Proc Roy Soc. 1934;A 145:362–387.
  • Orowan E. Zur Kristallplastizät III: Über die Mechanismus der Gleitvorganges. Zeitschrift Für Physik. 1934;89:634–659.
  • Polanyi M. Über ein Art Gitterstörung, die einen Kristall plastisch machen könnte. Zeitschrift Für Physik. 1934;89:660–664.
  • Burgers JM. Some considerations of the field of stress connected with dislocations in a regular crystal lattice. Koninklijke Nederlandse Akademie Van Wetenschappen. 1939;42(Part I):293–325. 378–399 (Part II).
  • Burgers JM. Geometrical considerations concerning the structural irregularities to be assumed in crystals. Proc. Phys.Soc. 1940  v52,  pp23-33 .
  • Burton WK, Cabrera N, Frank FC. Role of dislocations in crystal growth. Nature. 1949;163:398–399.
  • Menzies AWC, Sloat CA. Spiral markings on carborundum crystals. Nature. 1929;163:348–349. London.
  • Frank FC. Crystal dislocations. Elementary concepts and definitions. Phil. Mag. 1951;42(331):809–819.
  • Friedel J. Graine de mandarin.Paris: Odile Jacob; 1994.
  • Frank FC. On the theory of liquid crystals. Discuss Faraday Soc. 1958;25:19–28.
  • Leslie FM. Some constitutive equations for liquid crystals. Archive for Rational Mechanics and Analysis. 1968;28(4):265–283.
  • Orsay, Liquid, Crystal, Group, Lignes doubles de désinclinaison dans les cristaux liquides cholestériques a grands pas. Journal De Physique Colloques. 1969;30(C4):C4–38.
  • Kleman M, Friedel J. Lignes de dislocation dans les cholestériques. Le Journal De Physique Colloques. 1969;30(C4):C4–43.
  • Bouligand Y, Kléman M. Paires de disinclinaisons hélicodales dans les cholestériques. Journal De Physique. 1970;31(11–12):1041–1054.
  • Bellini T, Chiccoli C, Pasini P, et al. Monte Carlo study of liquid-crystal ordering in the independent-pore model of aerogels. Phys Rev. 1996;E 54(3):2647.
  • Bellini T, Buscaglia M, Chiccoli C, et al. Nematics with quenched disorder: what is left when long range order is disrupted? Phys Rev Lett. 2000;85(5):1008.
  • Bellini T, Buscaglia M, Chiccoli C, et al. Nematics with quenched disorder: how long will it take to heal? Phys Rev Lett. 2002;88(24):245506.
  • Rotunno M, Buscaglia M, Chiccoli C, et al. Nematics with quenched disorder: pinning out the origin of memory. Phys Rev Lett. 2005;94(9):097802.
  • Buscaglia M, Bellini T, Chiccoli C, et al. Memory effects in nematics with quenched disorder. Phys Rev. 2006;E 74(1):011706.
  • Cleaver DJ, Kralj S, Sluckin TJ, et al. The random anisotropy nematic spin model. In: Crawford GP, Zumer S, Eds. Liquid crystals in complex geometries. Taylor & Francis; 1996. p. 467–482.
  • Ranjkesh A, Ambrožič M, Kralj S, et al. Computational studies of history dependence in nematic liquid crystals in random environments. Phys Rev. 2014;E 89(2):022504.
  • De Gennes P-G. Short range order effects in the isotropic phase of nematics and cholesterics. Molecular Crystals Liquid Crystals. 1971;12(3):193–214.
  • Ball JM. Mathematics and liquid crystals. Molecular Crystals Liquid Crystals. 2017;647(1):1–27.
  • Poniewierski A, Sluckin TJ. On the free energy density of non-uniform nematics. Mol Phys. 1985;55(5):1113–1127.
  • Longa L, Monselesan D, Trebin H-R. An extension of the landau-ginzburg-de gennes theory for liquid crystals. Liq Cryst. 1987;2(6):769–796.
  • Schopohl N, Sluckin TJ. Defect core structure in nematic liquid crystals. Phys Rev Lett. 1987;59(22):2582.
  • Biscari P, Guidone Peroli G, Sluckin TJ. The topological microstructure of defects in nematic liquid crystals. Molecular Crystals and Liquid Crystals Science and Technology. Section A. Molecular Crystals and Liquid Crystals. 1997;292(1):91–101.
  • Schopohl N, Sluckin TJ. Hedgehog structure in nematic and magnetic systems. Journal De Physique. 1988;49(7):1097–1101.
  • Penzenstadler E, Trebin H-R. Fine structure of point defects and soliton decay in nematic liquid crystals. Journal De Physique. 1989;50(9):1027–1040.
  • Mkaddem S, Gartland E Jr. Fine structure of defects in radial nematic droplets. Phys Rev. 2000;E 62(5):6694.
  • Hudson SD, Larson RG. Monte Carlo simulation of a disclination core in nematic solutions of rodlike molecules. Phys Rev Lett. 1993;70(19):2916.
  • Chiccoli C, Pasini P, Semeria F, et al. Monte Carlo simulation of the hedgehog defect core in spin systems. Journal De Physique II. 1995;5(3):427–436.
  • Lavrentovich OD, Pasini P, Zannoni C, et al. Defects in liquid crystals: computer simulations, theory and experiments. Vol 43 of NATO Science Series in Mathematics, Physics and Chemistry.Dordrecht: Kluwer Academic Publishers; 2001.
  • Chiccoli C, Pasini P, Feruli I, et al. Computer simulations and defects in confined liquid crystal lattice models. In: Defects in liquid crystals: computer simulations, theory and experiments. Dordrecht: Springer; 2001. p. 87–112.
  • Kleman M, Lavrentovich OD. Topological point defects in nematic liquid crystals. Philosophical Magazine. 2006;86(25–26):4117–4137.
  • Chiccoli C, Feruli I, Lavrentovich O, et al. Topological defects in schlieren textures of biaxial and uniaxial nematics. Phys Rev. 2002;E 66(3):030701.
  • Chiccoli C, Pasini P, Feruli I, et al. Simulations of topological defects in nematic liquid crystal films. Molecular Crystals Liquid Crystals. 2003;398(1):195–206.
  • Bates MA, Skačej G, Zannoni C. Defects and ordering in nematic coatings on uniaxial and biaxial colloids. Soft Matter. 2010;6(3):655–663.
  • Chiccoli C, Pasini P, Evangelista LR, et al. Lattice spin simulations of topological defects in nematic films with hybrid surface alignments. Int J Mod Phys C. 2011;22(05):505–516.
  • Vanzo D, Ricci M, Berardi R, et al. Shape, chirality and internal order of freely suspended nematic nanodroplets. Soft Matter. 2012;8(47):11790–11800.
  • Luckhurst GR, Sluckin TJ. Biaxial nematic liquid crystals: theory, simulation and experiment. Chichester: John Wiley & Sons; 2015.
  • Chiccoli C, Evangelista L, Pasini P, et al. On the defect structure of biaxial nematic droplets. Scientific Reports. 2018;8(1):2130.
  • Weeks JD, Chandler D, Andersen HC. Role of repulsive forces in determining the equilibrium structure of simple liquids. J Chem Phys. 1971;54(12):5237–5247.
  • Ornstein LS, Zernike F. Accidental deviations of density and opalescence at the critical point of a single substance. Proceedings of the Royal Netherlands Academy of Arts and Sciences. 1914;17:793–806. English version available from. http://www.dwc.knaw.nl/DL/publications/PU00012727.pdf
  • De Gennes PG, Prost J. The physics of liquid crystals. 2nd Edition ed. Oxford: Clarendon Press; 1993. it is the 1974 first edition by de Gennes alone to which I am referring, rather than this jointly authored version.
  • Luckhurst GR, Gray GW. The molecular physics of liquid crystals.London: Academic Press; 1979.
  • Zannoni C. Distribution functions and order parameters. The molecular physics of liquid crystals. Luckhurst GR, Gray GW, Eds. Academic Press; London. 1979. 3. 51–83.
  • Frank FC. Quasi-kristalline und kristalline flussigkeiten. Physikalische Zeitschrift. 1939;39:530–534.
  • Kléman M. Points, lignes, parois. de Physique. Éd. Paris  1978.

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