References
- Huang C-Y, Lin Y-R, Lo K-Y, et al. Dynamics of photoalignment in azo-dye-doped liquid crystals. Appl Phys Lett. 2008;93(18):181114.
- Quiroga JA, Canga I, Alonso J, et al. Reversible photoalignment of liquid crystals: a path toward the creation of rewritable lenses. Sci Rep. 2020;10(1):1–9.
- Chigrinov V, Kozenkov V, and Kwok H. Photoaligning: physics and applications in liquid crystal devices. Hoboken: Wiley VCH; 2008.
- Wang J, McGinty C, Reich R, et al. Process for a reactive monomer alignment layer for liquid crystals formed on an azodye sublayer. Materials. 2018;11(7):1195.
- 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(2):021701.
- Chigrinov V, Guo Q, Kudreyko A. Photo-aligned ferroelectric liquid crystal devices with novel electro-optic characteristics. Crystals. 2020;10(7):563.
- Chigrinov V, Kudreyko A, Guo Q. Patterned photoalignment in thin films: physics and applications. Crystals. 2021;11(2):84.
- Chigrinov V, Pikin S, Verevochnikov A, et al. Diffusion model of photoaligning in azo-dye layers. Phys Rev E. 2004;69(6):061713.
- Norikane Y, Uchida E, Tanaka S, et al. Photoinduced crystal-to-liquid phase transitions of azobenzene derivatives and their application in photolithography processes through a solid–liquid patterning. Org Lett. 2014;16(19):5012–5015.
- Valyukh I, Arwin H, Chigrinov V, et al. UV‐induced in‐plane anisotropy in layers of mixture of the azo‐dyes SD‐1/SDA‐2 characterized by spectroscopic ellipsometry. Physic Status Solidi C. 2008;5(5):1274–1277.
- Cimrová V, Neher D, Hildebrandt R, et al. Comparison of the birefringence in an azobenzene-side-chain copolymer induced by pulsed and continuous-wave irradiation. Appl Phys Lett. 2002;81(7):1228–1230.
- Pan S, Ho JY, Chigrinov VG, editors. 44‐2: ultra‐thin high‐dichroic‐ratio polarizer generated by photoalignment. SID Symposium Digest of Technical Papers, Wiley Online Library; 2016.
- Wang B, Oakberg TC. A new instrument for measuring both the magnitude and angle of low level linear birefringence. Rev Sci Instrum. 1999;70(10):3847–3854.
- Benoit H. Study of the Kerr effect by dilute solutions of rigid macromolecules. Ann Phys(Paris). 1951;6:561–609.
- Morita A, Watanabe H. An exact treatment of the Kerr‐effect relaxation in a strong unidirectional electric field. J Chem Phys. 1979;70(10):4708–4713.
- Dadivanyan AK, Nazarov AP, Barabanova NN, et al. Relation between dichroism of photoalignment azo dyes and their orientation under light wave field. J Soc Inf Display. 2018;26(8):477–482.
- Sun J, Ren L, Deng K, et al. Greyscale generation for optically driving liquid crystal display. Liq Cryst. 2019;46(9):1340–1344.
- Yavrian A, Asatryan K, Galstian T, et al. Real-time holographic image restoration in azo dye doped polymer films. Opt Commun. 2005;251(4–6):286–291.
- Ghosh S, Carlisle G. Carbon nanotube enhanced diffraction efficiency in dye-doped liquid crystal. J Mater Sci. 2005;16(11):753–759.
- Hu W, Chen P, Lu YQ. Photoinduced liquid crystal domain engineering for optical field control. Photoactive Fun Soft Mater. 2019:361–387.