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Molecular Crystals and Liquid Crystals Science and Technology. Section A. Molecular Crystals and Liquid Crystals Volume 367, 2001 - Issue 1
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8. NOVEL INSTRUMENTATION FOR LIQUID CRYSTAL RESEARCH

A New Measurement Method for Ion Density in TFT-LCD Panels

Nobuyoshi Sasaki Analysis Technology Development Division, NEC Corporation 1753 Shimonumabe, Nakahara-ku, Kawasaki, Kanagawa, 211-8666, Japan
Pages 671-679 | Published online: 24 Sep 2006

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O. V. Kovalchuk, Anatoliy Glushchenko & Yuriy Garbovskiy. (2023) Improving experimental procedures for assessing electrical properties of advanced liquid crystal materials. Liquid Crystals 50:1, pages 140-148.
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Articles from other publishers (17)

Rajratan Basu. (2023) Utilizing 2D materials in liquid crystal–based electro-optic devices: A perspective. Applied Physics Letters 123:9.
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Oleksandr V. Kovalchuk, Tetiana M. Kovalchuk & Yuriy Garbovskiy. (2023) Eliminating Ambiguities in Electrical Measurements of Advanced Liquid Crystal Materials. Crystals 13:7, pages 1093.
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Rajratan Basu & Derek T. Gess. (2023) Ion trapping, reduced rotational viscosity, and accelerated electro-optic response characteristics in gold nano-urchin–nematic suspensions. Physical Review E 107:2.
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Yuriy Garbovskiy. (2021) Conventional and unconventional ionic phenomena in tunable soft materials made of liquid crystals and nanoparticles. Nano Express 2:1, pages 012004.
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Rajratan Basu & Lukas J. Atwood. (2019) Reduced ionic effect and accelerated electro-optic response in a 2D hexagonal boron nitride planar-alignment agent based liquid crystal device. Optical Materials Express 9:3, pages 1441.
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G B Hadjichristov, T E Vlakhov & Y G Marinov. (2019) Impedance and dielectric spectroscopy study of graphene-doped liquid crystal E7. Journal of Physics: Conference Series 1186, pages 012032.
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Y G Marinov, G B Hadjichristov, P M Rafailov, S H Lin, V M Marinova & A G Petrov. (2019) Optical, electro-optical, electrical and dielectric characterization of nematic liquid crystal (E7) layers doped with graphene nanoparticles for electro-optics. Journal of Physics: Conference Series 1186, pages 012031.
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Georgi B. Hadjichristov, Yordan G. Marinov, Todor E. Vlakhov & Alexander G. Petrov. Graphene-nematic liquid crystal E7 nanocomposite: The effect from nanodopants. Graphene-nematic liquid crystal E7 nanocomposite: The effect from nanodopants.
Kaushlendra Agrahari, Govind Pathak, Tripti Vimal, Katarzyna Kurp, Atul Srivastava & Rajiv Manohar. (2018) Dielectric and spectroscopic study of nano-sized diamond dispersed ferroelectric liquid crystal. Journal of Molecular Liquids 264, pages 510-514.
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Rajratan Basu & Andrew Lee. (2017) Ion trapping by the graphene electrode in a graphene-ITO hybrid liquid crystal cell. Applied Physics Letters 111:16.
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Yuriy Garbovskiy & Iryna Glushchenko. (2015) Nano-Objects and Ions in Liquid Crystals: Ion Trapping Effect and Related Phenomena. Crystals 5:4, pages 501-533.
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Rajratan Basu, Alfred Garvey & Daniel Kinnamon. (2015) Effects of graphene on electro-optic response and ion-transport in a nematic liquid crystal. Journal of Applied Physics 117:7.
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Rajratan Basu & Alfred Garvey. (2014) Effects of ferroelectric nanoparticles on ion transport in a liquid crystal. Applied Physics Letters 105:15.
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H Y Chen, K X Yang & Z Y Lin. (2010) Electrodynamic behaviour of nematic liquid crystal in a relaxation process. Journal of Physics D: Applied Physics 43:31, pages 315103.
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A. L. Alexe-Ionescu, G. Barbero & I. Lelidis. (2009) Models for ionic contribution to the complex dielectric constant of nematic liquid crystals. Physical Review E 80:6.
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Sung-Hee Hwang, Kangbaek Kim, Won Rae Kim & Dong-Soo Shin. (2009) Ion Transport in a Reflective Liquid-Crystal-on-Silicon Microdisplay Cell. Japanese Journal of Applied Physics 48:5R, pages 051503.
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G. Stojmenovik, S. Vermael, K. Neyts, R. van Asselt & A. R. M. Verschueren. (2004) Dependence of the lateral ion transport on the driving frequency in nematic liquid crystal displays. Journal of Applied Physics 96:7, pages 3601-3608.
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