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1 - Introduction

Published online by Cambridge University Press:  23 July 2017

Sandeep Kumar
Affiliation:
Raman Research Institute, Bangalore, India
Santanu Kumar Pal
Affiliation:
Indian Institute of Science Education and Research, Mohali, India
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Summary

LIQUID CRYSTALS

Liquid crystals (LCs) are distinctive functional soft materials with a combination of order and mobility on a molecular, supramolecular and macroscopic level. Hierarchical self-assembly in LCs offers a powerful strategy for producing nanostructured mesophases. Molecular shape, microsegregation of incompatible parts, specific molecular interaction, self-assembly and selforganization are important factors that lead to the formation of various LC phases. LCs are accepted as the fourth state of matter after solid, liquid and gas. This fourth state of matter is intermediate between the solid and the liquid state. For this reason, they are referred to as intermediate phases or mesophases. This is a real thermodynamic stable state of matter where the constituents of a mesophase are called mesogens. A rigid core of the mesogen (which often consists of aromatic rings) induces structural order whereas the flexible parts (e.g., alkyl chains) provide the necessary mobility within the LC phase.

The unique feature of LCs is the presence of both order and high degree of mobility in the mesophase that leads to the self-healing, adaptive and stimuli-responsive behaviour of these supramolecular systems and because of this, LCs have become the quintessential self-assembling molecular materials of the modern era. LCs have made huge impact on the development of the human societies. LCs are the advanced technological material found in lowpower- consuming LC displays (LCDs) which are being used in the last decades for the development of mobile data processing and communication tools. It is quite possible that LCDs might be replaced by other technologies in the future but, the fundamental knowledge gained with LCs can be used for the self-assembly of a huge variety of other materials.

In 1888, Friedrich Reinitzer, Professor of Botany and Technical Microscopy at the German Technical University in Prague found that the compound cholesteryl benzoate which he had extracted from carrots exhibited two melting points, one at 145.5 °C and other at 178.5 °C. Between these two melting points, there was a milky liquid phase. Above 178.5 °C, the phase became clear. He observed distinct violet and blue colour phenomena at both these two different melting points under polarizing optical microscope. After having similar observations with a further derivative cholesteryl acetate that has a monotropic cholesteric phase, he contacted physicist Otto Lehmann.

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Publisher: Cambridge University Press
Print publication year: 2017

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References

Collings, P. J. 2002. Liquid Crystals: Nature's Delicate Phase of Matter. Princeton, NJ: Princeton University Press.
Collings, P. J., and Hird, M. 1997. Introduction to Liquid Crystals: Chemistry and Physics. London, U.K: Taylor & Francis.
Kumar, S. 2011. Chemistry of Discotic Liquid Crystals: From Monomers to Polymers. Boca Raton, FL: CRC Press, Taylor & Francis Group.
Lagerwall, J. P. F., and Scalia, G. 2012. ‘A new era for liquid crystal research: Applications of liquid crystals in soft matter nano-, bio- and microtechnology’. Curr Appl Phys 12: 1387–412.Google Scholar
Hird, M. 2007. ‘Fluorinated liquid crystals—Properties and applications’. Chem Soc Rev 36: 2070–95.Google Scholar
Kawamoto, H. 2002. ‘The history of liquid-crystal displays’. Proc IEEE 90:460–500.Google Scholar
Haas, W. E. 1983. ‘Liquid crystal display research: The first fifteen years’. Mol Cryst Liq Cryst 94:1–31.Google Scholar
Bremer, M., Kirsch, P., Klasen-Memmer, M., and Tarumi, K. 2013. ‘The TV in your pocket: Development of liquid-crystal materials for the new millennium’. Angew Chem Int Ed 52:8880–96.Google Scholar
Mitov, M. 2014. ‘Liquid-crystal science from 1888 to 1922: Building a revolution’. ChemPhysChem 15:1245–50.Google Scholar
Geelhaar, T., Griesar, K., and Reckmann, B. 2014. ‘125 years of liquid crystals—A scientific revolution in the home’. Angew Chem Int Ed 52:8798–809.Google Scholar
Demus, D. 1988. ‘100 years liquid crystal chemistry’. Mol Cryst Liq Cryst 165:45–84.Google Scholar
Chandrasekhar, S. 1993. ‘Discotic liquid crystals: A brief review’. Liq Cryst 14:3–14.Google Scholar
Kumar, S. 2006. ‘Self-organization of disc-like molecules: Chemical aspects’. Chem Soc Rev 35:83–109.Google Scholar
Sergeyev, S., Pisula, W., and Geerts, Y. H. 2007. ‘Discotic liquid crystals: A new generation of organic semiconductors’. Chem Soc Rev 36:1902–29.Google Scholar
Bushby, R. J., and Lozman, O. R. 2002. ‘Discotic liquid crystals 25 years on’. Curr Opin Colloid Interface Sci 7:343–54.Google Scholar
Kaafarani, B. R. 2011. ‘Discotic liquid crystals for opto-electronic applications’. Chem Mater 23:378–96.Google Scholar
Bushby, R. J., and Kawata, K. 2011. ‘Liquid crystals that affected the world: Discotic liquid crystals’. Liq Cryst 38:1415–26.Google Scholar
Demus, D., Goodby, J., Gray, G. W., Spiess, H.-W., and Vill, V. 1998. Handbook of Liquid Crystals Vol. 2A: Low Molecular Weight Liquid Crystals I. Weinhiem: John Wiley & Sons.
Takezoe, H., and Takanishi, Y. 2006. ‘Bent-core liquid crystals: Their mysterious and attractive world’. Jpn J Appl Phys 45:597–625.Google Scholar
Reddy, R. A., and Tschierske, C. 2006. ‘Bent-core liquid crystals: Polar order, superstructural chirality and spontaneous desymmetrisation in soft matter systems’. J Mater Chem 16:907–61.Google Scholar
Etxebarriaa, J., and Ros, M. B. 2008. ‘Bent-core liquid crystals in the route to functional materials’. J Mater Chem 18:2919–26.Google Scholar
Griffin, A. C., and Britt, T. R. 1981. ‘Effect of molecular structure on mesomorphism. 12. Flexible-center Siamese-twin liquid crystalline diesters—A “prepolymer” model’. J Am Chem Soc 103:4957–9.Google Scholar
Vorlander, D. 1927. ‘Nature of the carbon chain in liquid crystal substances’. Z Phys Chem 126:449–72.Google Scholar
Imrie, C. T., and Henderson, P. A. 2007. ‘Liquid crystal dimers and higher oligomers: Between monomers and polymers’. Chem Soc Rev 36:2096–124.Google Scholar
Shanker, G., and Yelamaggad, C. V. 2011. ‘Synthesis and phase transitional behavior of dimer-like optically active liquid crystals’. J Phys Chem B 115:10849–59.Google Scholar
Goodby, J. W. 2002. ‘Twist grain boundary and frustrated liquid crystal phases’. Curr Opin Colloid Interface Sci 7:326–32.Google Scholar
Hiremath, U. S., Sonar, G. M., Rao, D. S. S., and Yelamaggad, C. V. 2011. ‘Wide thermal range frustrated liquid crystal phase in chiral dimers’. J Mater Chem 21:4064–7.Google Scholar
Kitzerow, H.-S. 2006. ‘Blue phases at work’. ChemPhysChem 7:63–6.Google Scholar
Coles, H. J., and Pivnenko, M. N. 2005. ‘Liquid crystal “blue phases” with a wide temperature range’. Nature 436:997–1000.Google Scholar
Radhika, S., Sadashiva, B. K., and Raghunathan, V. A. 2013. ‘Apolar novel mesogenic symmetric dimers composed of five-ring bent-core monomeric units’. Liq. Cryst. 40:1209–22.Google Scholar
Umadevi, S., Sadashiva, B. K., Murthy, H. N. S., and Raghunathan, V. A. 2006. ‘Mesogenic dimers composed of bent-core molecules with flexible alkylene spacer’. Soft Matter 2:210–4.Google Scholar
Schröder, M. W., Brand, K., Pelzl, G., Baumeister, U., Diele, S., and Weissflog, W. 2008. ‘Unusual electrooptical response of an oblique columnar phase formed by a bent-core mesogen’. Liq. Cryst. 35:325–31.Google Scholar
Shanker, G., Prehm, M., and Tschierske, C. 2011. ‘Laterally connected bent-core dimers and bent-core-rod couples with nematic liquid crystalline phases.’ J. Mater. Chem. 22:168–74.Google Scholar

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