| 摘要(英) |
The main topic reported in this study is waveguide liquid crystal (LC)
devices with asymmetrical light scattering property and their applications. The
key points we discuss herein include the asymmetrical light scattering optical
characteristics when an edge light source is coupled into the proposed three
different LC devices applied with suitable electric fields, and then scattered out of
the LC devices. They are (i) polymer network LC (PNLC) cell coated with a low
refractive index thin film (MgF2), (ii) PNLC cell with cholesteric LC polymer
(CLCP) layers, and (iii) twisted hybrid aligned PNLC (TH-PNLC) cell with a
linear polarizer. We are going to explain the principle and the functional
characteristics of the structures of each LC device.
First of all, we discuss the properties of a homogeneous aligned PNLC (HA�PNLC) cell whose one substrate is coated with a thin film having low refractive
index. Such a low refractive index magnesium fluoride (MgF2) film is deposited
on the top of the indium-tin-oxide film of one of the substrates of the LC cell by
evaporation method. The main mechanisms adopted here are the properties of LC
waveguide and total internal reflection (TIR). Based on the different times of TIR
of the incident light source, occurred on the boundaries of different films, the
asymmetrical output light in its scattering state can be obtained. The second part
is the asymmetrical light scattering properties demonstrated by the proposed HA�PNLC cell with a CLCP layer. Due to the limitation of the CLCP layer, the edge
light source selected herein is a He-Ne laser with its wavelength of 632.8 nm,
which is within the reflection band of the used CLCP layer. Briefly, the powers of
light scattered out of the LC device from the sides with and without the CLCP
layer are different, indicating that the asymmetrical light scattering property can
also be realized. The last part of the research about asymmetrical light scattering
property is based on the proposed TH-PNLC cell with a linear polarizer. The
surface treatments of the two substrates of the TH-PNLC cell are different, one is
iv
homogeneous alignment, and the other one is homeotropic alignment. Moreover,
the twisted and hybrid aligned PNLC structures provide light scattering with
different degrees of polarization from two sides of TH-PNLC cell applied with
suitable electric fields. Therefore, we can realize asymmetrical light scattering
property with one polarizer stuck on the side of the TH-PNLC cell treated with a
homeotropic alignment layer.
Finally, the three LC devices mentioned above can be applied to various
practical applications in daily life. In this thesis, the applications of the proposed
waveguide LC devices, including electrically switchable one-way transparent
light sources, switchable LC privacy smart windows, and LCDs with privacy
protection, have also been demonstrated. However, lots of challenges, such as
contrast, operation voltage, uniformity, etc., still need to be overcome |
| 參考文獻 |
參考文獻
[1] X. Zhou, G. Qin, L. Wang, Z. Chen, X. Xu, Y. Dong, A. Moheghi, and D. K.
Yang, “Full color waveguide liquid crystal display,” Opt. Lett. 42, 3706-3709
(2017).
[2] 陳維軒,利用扭轉型聚合物網絡液晶製作偏振選擇性光散射之研 究(國
立中央大學,碩士論文,民國 105 年)
[3] C. K. Liu, W. H. Chen, and K. T. Cheng, “Asymmetrical polarization�dependent scattering and reflection in a sole cell of polymer network-90°
twisted nematic liquid crystals,” Opt. Express 25, 22388-22403 (2017).
[4] D. Dunmur and T. Sluckin, “Soap, Science, and Flat-screen TVs: a history of
liquid crystals,” Oxford University Press, USA (2011).
[5] P.M. Knoll and H. Kelker, “Otto Lehmann - Erforscher der flüssigen Kristalle.
Eine Biographie mit Briefen an Otto Lehmann,” Privatpublikation, Ettlingen
(1988).
[6] T. J. Sluckin, D. A. Dunmur, and H. Stegemeyer, “Crystals that flow. Classic
papers from the history of liquid crystals,” CRC Press, London (2004).
[7] P. G. de. Gennes and J. Prost, “The Physics of Liquid Crystal,” 2nd ed.,
Oxford (1993).
[8] 松本正ㄧ、角田市良,液晶之基礎與應用,國立編譯館,(1996)。
[9] M. Mitov, “Cholesteric Liquid Crystals with a Broad Light Reflection Band,”
Adv. Mater. 24, 6251-6383 (2012).
[10]R. J. A. Tough and M. J. Bradshaw, “The determination of the order
parameters of nematic liquid crystals by mean field extrapolation,” J. Phys.
44, 447-454 (1983).
[11]P. J. Collings and M. Hird, “Introduction to Liquid Crystals: Chemistry and
Physics,” CRC Press, London (1997).
[12]D. Andrienko, “Introduction to liquid crystals,” J. Mol. Liq. 267, 520-541
(2018).
[13]J. Thomas and Y. Heights, “Thermodynamic and static properties of liquid
crystals,” Prog. Solid. State Ch., 10, 103-118(1975).
[14]F. Reinitzer, “Beiträge zur kenntnis des cholesterins,” Monatsh. Chem. 9,
421-441 (1888).
145
[15]G. W. Gray, “Molecular Structure and the Properties of Liquid Crystals,”
Academic Press., London (1962).
[16]Y. H. Lin, M. S. Chen, W. C. Lin, and Y. S Tsou, “A polarization-independent
liquid crystal phase modulation using polymer-network liquid crystals in a
90° twisted cell,” J. Appl. Phys. 112, 8746-8752 (2012).
[17]A. Y. G. Fuh, M. H. Li, T. W. Chang, Y. I. Lee, and S. T. Wu, “Optical
manipulation of nematic colloids at the interfaces in azo-dye-doped liquid
crystals,” Appl. Opt. 57, 3180-3185 (2018).
[18]M. Mohammadimasoudi, J. Beeckman, Z. Hens, and K. Neyts, “Hybrid
fluorescent layer emitting polarized light,” APL Mater. 5, 076104 (2017).
[19]E. Munin, C. B. Pedroso, and A. B. Villaverde, “Magneto-optical constants
of fluoride optical crystals and other AB2 and A2B type compounds,” J. Chem.
SOC., Faraday Trans. 92, 2753-2757 (1996).
[20]T. A. Kumar, K. V. Le, S. Aya, S Kang, F. Araoka, K. Ishikawa, S. Dhara, and
H. Takezoe, “Anchoring transition in a nematic liquid crystal doped with
chiral agents,” Phase Transit. 85, 888-899 (2012).
[21]S. D’Elia, V. Barna, N. Scaramuzza, G. Strangi, and R. Bartolino, “The
influence of drying temperature on the close packed structure of silanized
monolayers deposited on indium tin oxide (ITO) substrates,” J. Mater. Res.
24, 2784-2794 (2009).
[22]A. Moheghi, G. Qin, and D. K Yang, “Stable polarizing light waveguide plate
for edgelit liquid crystal displays,” Opt. Mater. Express 6, 429-435 (2016).
[23]J. H. Jung, D. M. Lee, J. H. Kim, and C. J. Yu, “Circularly polarized
electroluminescence by controlling emission zone in twisted mesogenic
conjugate polymer,” J. Mater. Chem. C. 6, 726-730 (2018).
[24]F. M. Ali, R. M. Kershi, M. A. Sayed, and Y. M. AbouDeif, “Evaluation of
structural and optical properties of Ce3+ ions doped (PVA/PVP) composite
films for new organic semiconductors,” Physica B Condens. Matter. 538,
160-166 (2018).
[25]M. Honma, Y. Kasai, and T. Nose, “Stokes imaging polarimetry using a
twisted hybrid aligned nematic liquid crystal cell,” Appl. Opt. 57, 9649-9656
(2018).
[26]D. Y. Kim, K. M. Lee, T.J. White, and K. U.Jeong, “Cholesteric liquid crystal
paints: in situ photopolymerization of helicoidally stacked multilayer
nanostructures for flexible broadband mirrors,” NPG Asia Mater. 10, 1061-
146
1068 (2018).
[27]G. Agez and M. Mitov, “Cholesteric Liquid Crystalline Materials with a Dual
Circularly Polarized Light Reflection Band Fixed at Room Temperature,” J.
Phys. Chem. B 115, 6421-6426 (2011). |
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