Open Access Open Access  Restricted Access Subscription or Fee Access

The Practical Use of Cholesteric Liquid Crystal Film for Development of New Technologies

Michael Shoikhedbrod

Abstract


The use of cholesteric liquid crystal films, using the remarkable property of cholesteric liquid crystals to change their color at the temperature changes, is well known for measuring temperature, in medicine, in jewelry and so on. The article presents the practical use of cholesteric liquid crystal films in the developed musical color device, which “animates” the pattern with a multi-colored color in accordance with the frequency spectrum of the signal emanating from the musical electronic device on the black panel, and in the developed indicator of sorption processes, which highlights by the red color the collector's coating of the surface of the mineral safely, cheaply and quickly

Keywords


Cholesteric liquid crystals films; breast cancer; music color device; indicator of sorption processes; optical properties of cholesteric liquid crystals, temperature change.

Full Text:

PDF

References


Shibaev V.P. (2008). Liquid crystals-cholesterics: Chemistry and Life [online]. Available from http://www.chem.msu.ru/rus/teaching/shibajev-nauchpop/shibajev-himija.i.zhizn-2008.pdf.

Averyanov E.M. The special feature of the local field of light wave in the cholesteric liquid crystals, liquid crystals and their practical use. 2009; 28(2): 21–30.

Tomilin M.G., Nevskya G.E. (2010). Display on the liquid crystals: SPbGU[online]. Available from https://www.twirpx.com/file/288369/.

Shibaev V.P. (2012). Liquid crystals: Nature[online]. Available from http://www.chem.msu.ru/rus/teaching/shibajev-nauchpop/shibajev-priroda-2012-6.pdf.

Srivastava A.K., Tocnaye J.L., Dupont L. Liquid Crystal Active Glasses for 3D Cinema. Journal of display technology. 2010; 6(10): 522–530.

Popov P., Honaker L.W., Kooijman E.E., et al. A liquid crystal biosensor for specific detection of antigens. Sensing and Bio-Sensing Research. 2016; 8: 31–35.

Klyukin L.M., Morozov S.Yu. The analysis of the contemporary methods of diagnostics of breast cancer, medical technology, 2014, No 3.

Dogic Z., Sharma P., Zakhary M. Hypercomplex Liquid Crystals. Annual Review of Condensed Matter Physics. 2014; 5: 137–157.

Humar M., Musevic I. 3D microlasers from self-assembled cholesteric liquid crystal microdroplets. Optics Express. 2010; 18(26): 26995–27003.

Lu C., Chien L. A polymer-stabilized single-layer color cholesteric liquid crystal display with anisotropic reflection. Appl. Phys. Lett. 2007; 91(13).

Herzer N., Guneysu H., Davies D., Yildirim D., Vaccaro A. Printable Optical Sensors Based on H-Bonded Supramolecular Cholesteric Liquid Crystal Networks. J. Am. Chem. Soc. 2012; 134 (18): 7608–7611.

Kim K., Park K., Lee J., Yoon T. Long-pitch cholesteric liquid crystal cell for switchable achromatic reflection. Optics Express. 2010; 18(16): 16745–16750.

Hsiao Y., Wu C., Chen C., Zyryanov V., Lee W. Electro-optical device based on photonic structure with a dual-frequency cholesteric liquid crystal. Optics Letters. 2011; 36(14): 2632–2634.

Bitar R., Agez G., Mitov M. Cholesteric liquid crystal self-organization of gold nanoparticles. Soft Matter. 2011; 7: 8198–8206.

Shoikhedbrod M.P. Cholesteric liquid crystals. Toronto: Lambert Academic Publishing; 2017. 160p.


Refbacks

  • There are currently no refbacks.