International Journal of Nanomaterials and Nanostructures

Photoalignment has clear benefits in correlation with the ordinarily "scouring" treatment of the substrates of fluid precious stone presentation (LCD) cells. The fluid gem photoalignment is nano- innovation, as the thickness of the arrangement layer is around 2–15 nm. The use of the photograph arrangement and photograph designing nano innovation for the new age of photonic and show gadgets will be inspected. We discussed about LC polarization regulators, rotators, and variable optical attenuators with variable polarization parameters. We described Novel LC Display Devices in light of Nano-size photograph with high design innovation and highlighted nano technology use in LCD Devices. Optical rewritable innovation (ORW) technique is discussed and its advantages of using in LCD devices are highlighted. Also designed Micro size sensor using CMOS in LCD devices and enumerated its advantage of using in LCD Devices. New innovation in the Photo alignment is discussed with the new LC Photonic devices in Nano size and new photo pattern is explained. The working models developed with this technology will fetch intense displaying device in future. High resolution devices are the future and this LCD switches discussed in this paper is the need of the technology. Further the switches find numerous applications in the communication field. We also proposed fostered an extraordinary programming that gives us to enhance different LC cell designs to get ideal polarization plane of the information in terms of the light to the given point. The developed product can be utilized to find a application in electrooptical applications. Also finds various usage in Fiber optical communications with the advantage of less delay and timing for information processing with low controlling power and fastest communication purpose. The LC polarization regulator discussed here shows the condition of polarization to any state and condition of light polarization. Finally, we have discussed in detail the LC switches and advantage of Nanotechnology in Photonic field.

Chigrinov, Vladimir G. "Photoalignment and photopatterning in liquid crystal photonics."Emerging Liquid Crystal Technologies VII. Vol. 8279. SPIE, 2012.

Lightwaves2020 Lives On “Light Reading”. Light Reading. Published 2020. Accessed July 5, 2022. https://www.lightreading.com/lightwaves2020-lives-on/d/d-id/609073

Vescent Photonics “Laser Manufacturer and Supplier”. Vescent.com. Published 2022. Accessed July 5, 2022. https://vescent.com/in/

Presnyakov, Vladimir, Zhijian Liu, and Vladimir G. Chigrinov. "Fast optical retarder using deformed-helical ferroelectric liquid crystals." Photonic Applications in Devices and Communication Systems. Vol. 5970. SPIE, 2005.

Kiselev, Alexei D., et al. "Polarization-gratings approach to deformed-helix ferroelectric liquid crystals with subwavelength pitch." Physical Review E 83.3 (2011): 031703.

Pozhidaev, Evgeny Pavlovich, Vadim Evgenievich Molkin, and Vladimir Grigorievich Chigrinov. "Smectic nanostructures with typical size less than the visible light wavelength: physics and electro-optics." Photonics Letters of Poland 3.1 (2011): 11–13.

Chigrinov, Vladimir G. "Novel photoaligned fast ferroelectric liquid crystal display and photonics devices." (2011).

Fujisawa, T., et al. "V-shaped EO properties of polymer stabilized (PSV-) FLCD free from conventional surface stabilization: Advanced color sequential LCDs." IDW. Vol. 8. 2008.

Pozhidaev, E.P., et al. "Ferroelectric liquid crystal display cell with electrically suppressed helix."US Provisional Patent Application No. 61 457 (2011): 31.

Chigrinov, Vladimir G. "Fast switchable liquid crystal cells for field sequential color and 3D Displays." (2011).

Xu, Peizhi, Vladimir Chigrinov, and Hoi Sing Kwok. "Optical analysis of a liquid-crystal switch system based on total internal reflection." JOSA A 25.4 (2008): 866–873.

Pozhidaev, E.P., Vladimir G. Chigrinov, and Tao Du. "Fast switching bistable ferroelectric liquid crystal switches as a new optical element for photonics applications." 2009 14th OptoElectronics and Communications Conference. IEEE, 2009.

Muravsky, Alexander, and Vladimir G. Chigrinov. "Optical switch based on nematic liquid crystals." IDW/AD'05-Proceedings of the 12th International Display Workshops in Conjunction with Asia Display 2005. No. 1. 2005.

Maksimochkin, Alexander G., et al. "Electrically controlled waveguide mode in LC layer for fiber optic applications." Optics communications 283.16 (2010): 3136–3141.

Zhuang, Zhizhong, Seong-Woo Suh, and J. S. Patel. "Polarization controller using nematic liquid crystals." Optics letter 24.10 (1999): 694 696.

Muravsky, Alexander, et al. "Light printing of grayscale pixel images on optical rewritable electronic paper." Japanese journal of applied physics 47.8R (2008): 6347.

Presnyakov, Vladimir V., Zhijian J. Liu, and Vladimir G. Chigrinov. "Infiltration of photonic crystal fiber with liquid crystals." Nanophotonics for Communication: Materials and Devices II. Vol. 6017. SPIE, 2005.

Poon, Andrew W., et al. "Photonics filters, switches and subsystems for next-generation optical networks." HKIE Transactions 11.2 (2004): 60–67.

Chigrinov, Vladimir G., Vladimir M. Kozenkov, and Hoi-Sing Kwok. Photoalignment of liquid crystalline materials: physics and applications. John Wiley & Sons, 2008.

Semerenko, Denis, et al. "Optically controlled transmission of porous polyethylene terephthalate films filled with nematic liquid crystal." Optics letter 35.13 (2010): 2155–2157.

Chigrinov, Vladimir G., et al. "Electrically tunable microresonators using photoaligned liquid crystals." U.S. Patent No. 7,783,144. 24 Aug. 2010.

Presnyakov, Vladimir, et al. "Optical polarization grating induced liquid crystal micro-structure using azo-dye command layer." Optics express 14.22 (2006): 10558–10564.

Muravsky, Alexander, Fei Fan, and Vladimir G. Chigrinov. "Passive liquid crystal collimator integrated inside LC cell." (2008).

Murauski, Anatoli. "Device for optical driving of the rewritable optically addressed photoaligned liquid crystal device for display." JP 2007–092658 (2007).

Chigrinov, Vladimir G., et al. "Optically rewritable E-paper." (2011).

Sun, Jiatong, and Vladimir Chigrinov. "Effect of azo dye layer on rewriting speed of optical rewritable E-paper." Molecular Crystals and Liquid Crystals 561.1 (2012): 1–7.

Tseng, Man-Chun, et al. "Tunable lens by spatially varying liquid crystal pretilt angles." Journal of applied physics 109.8 (2011): 083109.

Zhao, Xiaojin, et al. "Thin photo-patterned micropolarizer array for CMOS image sensors." IEEE Photonics Technology Letters 21.12 (2009): 805-807.

Zhao, Xiaojin, et al. "High-resolution photoaligned liquid-crystal micropolarizer array for polarization imaging in visible spectrum." Optics letter 34.23 (2009): 3619–3621.

Zhao, Xiaojin, et al. "Liquid-crystal micropolarimeter array for full Stokes polarization imaging in visible spectrum." Optics express 18.17 (2010): 17776–17787.

Slussarenko, Sergei, et al. "Tunable liquid crystal q-plates with arbitrary topological charge." Optics express 19.5 (2011): 4085–4090.

Ganesh, E.N, “A Complete study and review of Characterization Techniques of Nano materials” Global Journal of Research in Engineering & Computer Sciences, (2022), 2 (2), 17–31.

Ganesh, E.N, “Investigation of Doubling heat capacity of storage fluids through nanomaterials” Indian Journal of Advanced Chemistry, (2022), 1 (3), 1–4.

Ganesh, E.N, “Fabrication and Study of Multiwall Carbon Nanotube based capacitor electrodes for Energy Storage Applications” Journal of Semiconductor Devices and Circuits, (2022), 8 (3),

–60.

Ganesh, E.N, “Study of Dynamic Mechanical and Thermal Properties of Poly (Ether Ether Ketone) Carbon Nanotubes” International Journal of Polymer Science & Engineering, (2017), 3 (1), 1–21.