References
- Schadt M. Nematic liquid crystals and twisted-nematic LCDs. Liq Cryst. 2015;42:646–652.
- Raynes EP, Sage IC. Chemicals to calculators: the early exploitation of cyanobiphenyl liquid crystals. Liq Cryst. 2015;42:722–731.
- Hanaoka K, Nakanishi Y, Inoue Y, et al. 40.1: a new MVA-LCD by polymer sustained alignment technology. SID Int Symp Dig Tech Pap. 2004;35:1200–1203.
- Kim SG, Kim SM, Kim YS, et al. Stabilization of the liquid crystal director in the patterned vertical alignment mode through formation of pretilt angle by reactive mesogen. Appl Phys Lett. 2007;90:261910-1–261910-3.
- Kim SM, Cho IY, Kim WI, et al. Surface-modification on vertical alignment layer using UV-curable reactive mesogens. Jpn J Appl Phys. 2009;48:032405-1–032405-5.
- Lee SH, Kim SM, Wu S-T S-T. Review paper: emerging vertical-alignment liquid-crystal technology associated with surface modification using UV-curable monomer. J Soc Inf Disp. 2009;17:551–559.
- Nakanishi Y, Hanaoka K, Shibasaki M, et al. Relation between monomer structure and image sticking phenomenon of polymer-sustained-alignment liquid crystal displays. Jpn J Appl Phys. 2011;50:051702-1–051702-5.
- Lyu JJ, Kikuchi H, Kim DH, et al. Phase separation of monomer in liquid crystal mixtures and surface morphology in polymer-stabilized vertical alignment liquid crystal displays. J Phys D. 2011;44:325104-1–325104-5.
- Mizusaki M, Nakanishi Y, Enomoto S. Fabrication of vertically aligned liquid crystal cell without using a conventional alignment layer. Liq Cryst. 2018;45:270‐278.
- Mizusaki M. Fabrication of vertical alignment liquid crystal cell without forming a conventional polyimide-alignment layer. Liq Cryst. 2019;46:1167‐1174.
- Bremer M, Naemura S, Tarumi K. Model of ion solvation in liquid crystal cells. Jpn J Appl Phys. 1998;37:L88–L90.
- Huang KT, Chao A, Yu CH. P-123: image sticking analysis of different Q-time LC cell by machine vision. SID Int Symp Dig Tech Pap. 2007;38:665–668.
- Park Y, Kim S, Lee E. A study on reducing image-sticking artifacts in wide-screen TFT-LCD monitors. J Soc Info Disp. 2007;15:969–973.
- Tanaka Y, Goto Y, Iimura Y. Mechanism of DC offset voltage generation in hybrid-aligned nematic liquid crystal displays. Jpn J Appl Phys. 1999;38:L1115–L1117.
- Mizusaki M, Miyashita T, Uchida T. Kinetic analysis of image sticking with adsorption and desorption of ions to a surface of an alignment layer. J Appl Phys. 2012;112: 044510-1–044510-9.
- Xu D, Peng F, Chen H, et al. Image sticking in liquid crystal displays with lateral electric fields. J Appl Phys. 2014;116:193102-1–193102-8.
- Nakanishi Y, Okamoto K. Relationship between concentration of initiator and image-sticking phenomenon of polymer-sustained-alignment liquid crystal displays. Jpn J Appl Phys. 2012;51:041701-1–041701-5.
- Moon Y-K, Lee Y-J, Yu C-J, et al. Four-domain twisted nematic structure with enhanced liquid crystal alignment stability and fast response time. J Appl Phys. 2012;112:014512-1–014512-5.
- Lee Y-J, Baek J-H, Kim Y, et al. Enhanced surface anchoring energy for the photo-alignment layer with reactive mesogens for fast response time of liquid crystal displays. J Phys D: Appl Phys. 2013;46:14305-1–14305-5.
- Mizusaki M, Yamada Y. Voltage holding properties of bend liquid crystal cells with treatments for bend alignment stabilisation. Liq Cryst. 2013;40:267–271.
- Mizusaki M, Nakanishi Y. Improvement of image sticking on liquid crystal displays with polymer layers produced from mixed monomers. Liq Cryst. 2016;43:704–710.
- Mizusaki M, Nakanishi Y, Enomoto S, et al. Evaluation of image sticking property on liquid crystal displays with polymer layers produced from phenanthrene-carrying monomers. Liq Cryst. 2016;43:1208–1214.
- Inoue M. Review of various measurement methodologies of migration ion influence on LCD image quality and new measurement proposal beyond LCD materials. J Sid. 2020;28:92–110.
- Han K-Y, Miyashita T, Uchida T. Accurate determination and measurement error of pretilt angle in liquid crystal cell. Jpn J Appl Phys. 1993;32:L277–L279.