https://orcid.org/0000-0002-1964-8558
References
- Muravsky A, Murauski A, Chigrinov V, et al. Lightprinting of grayscale pixel images on optical rewritable electronic paper. Jpn J Appl Phys. 2008;47:6347–6353.
- Guo Q, Srivastava AK, Pozhidaev EP, et al. Optimization of alignment quality of ferroelectric liquid crystals by controlling anchoring energy. Appl Phys Express. 2014;7:021701.
- Hu W, Srivastava A, Xu F, et al. Liquid crystal gratings based on alternate TN and PA photoalignment. Opt Express. 2012;20:5384–5391.
- Zhang W, Sun J, Srivastava AK, et al. 3-D grayscaleimages generation on optically rewritable electronicpaper. SID Symp Dig Tech Pap. 2015;46:40.
- Wang L, Sun J, Srivastava A, et al. Thermal stability ofgray-scale levels on optical rewritable electronic paper. IDW. 2011;11:1627–1628.
- Wu H, Hu W, Hu H, et al. Arbitrary photo-patterning in liquid crystal alignments using DMD based lithography system. Opt Express. 2012;20:16684–16689.
- Chigrinov VG, Kozenkov V, Kwok HS. Photoalignmentof liquid crystalline materials: physics and applications. Cornwall: Wiley; 2008.
- Liu Y, Lee JH, Seo DS, et al. Ion-beam-spurted dimethyl-sulfate-doped PEDOT: PSS composite-layer-aligning liquid crystal with low residual direct-current voltage. Appl Phys Lett. 2016;109:101901.
- Nie X, Lu R, Xianyu H, et al. Anchoring energy and cell gap effects on liquid crystal response time. J Appl Phys. 2007;101:103110.
- Kim Y, Lee YJ, Kim DH, et al. Fast response time of fringe-field switching liquid crystal mode devices with reactive mesogens in a planar alignment layer. J Phys D. 2013;46:485306.
- Lee YJ, Baek JH, 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. 2013;46:145305.
- Xu H, Davey A, Wilkinson T, et al. A simple method for optically enhancing the small electro-optical effects of fast switching electroclinic liquid crystals. Appl Phys Lett. 1999;74:3099–3101.
- Ha YS, Kim HJ, Park HG, et al. Enhancement of electro-optic properties in liquid crystal devices via titanium nanoparticle doping. Opt Express. 2012;20:6448–6455.
- Kumar V, Kumar A, Biradar AM, et al. Enhancement of electro-optical response of ferroelectric liquid crystal: the role of graphene quantum dots. Liq Cryst. 2014;41:1719–1725.
- Sano S, Miyama T, Takatoh K, et al. Enhancement of the characteristics of LCDs by doping nanoparticles: reduction of the operating voltage, viscosity, and response times. Inter Soc Optics Photonics. 2006;6135:613501.
- Sun J, Chigrinov V. Effect of azo dye layer on rewriting speed of optical rewritable E-paper. Mol Cryst Liq Cryst. 2012;561:1–7.
- Yu G, Jiatong S, Murauski A, et al. Increasing the rewriting speed of optical rewritable e-paper by selecting proper liquid crystals. Chin Phys B. 2012;21:080701.
- Wang L, Sun J, Liu H, et al. Increasing the rewriting speed of ORW e-paper by electric field. Liq Cryst. 2018;45:553–560.
- Sun J, Liu Y, Liu H, et al. Increasing rewriting speed of optically driving liquid crystal display by process optimisation. Liq Cryst. 2019;46:151–157.
- Ge Z, Wu S-T, Kim SS, et al. Thin cell fringe-field-switching liquid crystal display with a chiral dopant. Appl Phys Lett. 2008;92:181109.
- Akagi K, Piao G, Kaneko S, et al. Helical polyacetylene synthesized with a chiral nematic reaction field. Science. 1998;282:1683–1686.
- Wang Y, Li Q. Light‐driven chiral molecular switches or motors in liquid crystals. Adv Mater. 2012;24:1926–1945.
- Eelkema R. Photo-responsive doped cholesteric liquid crystals. Liq Cryst. 2011;38:1641–1652.