Surface-assisted photoalignment in dye-doped liquid-crystal films

Lee, Chia Rong; Fu, Tingting; Cheng, Kuo-Hsing; Mo, Ting; Fuh, Andy Ying–Guey

doi:10.1103/physreve.69.031704

Cited by 69 publications

(64 citation statements)

References 12 publications

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“…This result elucidates further the physics of the DDLCs since previous works have found that only the adsorption of dyes is responsible for the surface anchoring energy during illumination. [5][6][7][8] For the DDLC cell under sufficient illumination, the surface anchoring energy that is provided by the adsorption of dyes is around double that provided by the preexisting-dye-induced torque. This result indicates that the adsorption of dyes dominates the reorientation of the polar director after illumination.…”

Section: B Calculation and Discussion Of Polar Anchoring Energy Of Dmentioning

confidence: 98%

“…[1][2][3][4] The director reorientation becomes permanent if the excited dye molecules are adsorbed on the boundary surface of the DDLC cell, leading to the alignment of the LC molecules and the appearance of anchoring energy. [2][3][4][5][6] The anchoring energies of the DDLC cells are obtained by measuring using a polarized optical microscope, 5 the pumpprobe twist nematic method 6,7 and measurement of Freedericksz transition. 8 Most studies of DDLC cells have focused on the azimuthal component of the anchoring energy; [5][6][7] few have considered the polar component.…”

Section: Introductionmentioning

confidence: 99%

“…[2][3][4][5][6] The anchoring energies of the DDLC cells are obtained by measuring using a polarized optical microscope, 5 the pumpprobe twist nematic method 6,7 and measurement of Freedericksz transition. 8 Most studies of DDLC cells have focused on the azimuthal component of the anchoring energy; [5][6][7] few have considered the polar component. 8 The polar anchoring energy in the DDLC cell importantly affects the electrooptical properties ͑such as response time and threshold voltage͒.…”

Section: Introductionmentioning

confidence: 99%

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Determination of polar anchoring energy of dye-doped liquid crystals by measuring capacitance

Huang

Cheng

et al. 2010

Journal of Applied Physics

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Polar anchoring energy of a dye-doped liquid crystal (DDLC) cell is determined based on capacity measurements. Experimental results indicate that under the illumination of a pump beam, the polar anchoring energy (7.90×10−6 J/m2) includes the adsorption-induced anchoring energy (5.74×10−6 J/m2) and the preexisting-dye-induced anchoring energy (2.16×10−6 J/m2). The latter is attributed to the torque, which is induced by the dye molecules on the boundary surface even before illumination. After the illumination, the adsorption-induced anchoring energy remains and the preexisting-dye-induced anchoring energy disappears, with the former revealing that weak anchoring affects the decay time and threshold voltage of the DDLC cell. Moreover, plotting the polar angle distributions in the DDLC cell reveals its correlation with variations in the capacitance of the DDLC cell.

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Section: B Calculation and Discussion Of Polar Anchoring Energy Of Dmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Determination of polar anchoring energy of dye-doped liquid crystals by measuring capacitance

Huang

Cheng

et al. 2010

Journal of Applied Physics

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“…Subsequent studies demonstrated that in LC that is doped with MR, lightinduced desorption from the spontaneously adsorbed MR layer results in the alignment of the LC perpendicular to the polarization upon exposure to light of weak intensity. Lee et al [42] suggested that the surface morphology of the adsorbed substrate depends considerably on not only the intensity but also the duration of the pumping. In the weak-intensity regime, the homogeneous and fine layer of adsorbed dyes and the layer with microgrooves dominate in the early and late stages, respectively, tending to cause the LCs to reorient perpendicular and parallel to the direction of polarization of the pump beam.…”

Section: Bulk-mediated Photo-isomerization and Adsorption Effectsmentioning

confidence: 99%

“…SEM and AFM were used to identify smooth layers of adsorbed molecules on the surfaces following exposures that caused the reorientation of the directors perpendicular to the direction of polarization and layers with well-oriented ripples upon exposures that caused alignment toward the direction of polarization [42,48]. The adsorbed layer consists of MR molecules with their long axes perpendicular to the ripples.…”

Section: Bulk-mediated Photo-isomerization and Adsorption Effectsmentioning

confidence: 99%

Photo-Alignment Technology

Lin

2014

Topics in Applied Physics

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LCDs are used in many everyday devices, including mobile phones, notebook computers and wide screen televisions. A typical LCD is composed of two glass substrates between which is a gap that is filled with LC. The arrangement of the LC is controlled by the boundary condition of an alignment film. A long-range orientational interaction causes the preferable alignment of a LC by the surface boundary to extend into the LC bulk. The alignment layer is typically rubbed with a special cloth to induce a unidirectional alignment of the LC. In the first devices based on twisted LCs, these LCs were aligned only by rubbing transparent electrodes. The rubbing technique became much more reliable when the glass substrate was covered with a rubbed polymer layer. The rubbing of polymers is a very simple technique and it is now extensively utilized in both small scientific laboratories and large LCD factories.Despite the extensive use of rubbing in LCD manufacturing, it has some serious shortcomings that arise from the contact involved in rubbing. These critically affect the production of the most recent generation of LCDs and miniature LC photonic devices. First, rotational rubbing for the polymer surface causes the accumulation of static charges and the formation of fine dust particles. The accumulation of static electricity may destroy the transistors or diodes in the LCD. The second shortcoming is the effect of decreasing in manufacturing yield. Rubbing for large and high-resolution active matrix LCDs (AMLCDs) involve additional difficulties that are associated with the precise control of the rubbing characteristics. Other problems are the difficulty of producing local structures with the required LC director alignment in the selected areas of the device. Finally, this method cannot be used to align LCs in closed volumes.For all of the above reasons, new alignment solutions and approaches are sought. There are some alternative methods of rubbing include laser writing, micro-rubbing, ion beam irradiation and photoalignment. Of these methods, the

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Light‐Patterned Crystallographic Direction of a Self‐Organized 3D Soft Photonic Crystal

et al. 2017

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Uniform and patterned orientation of a crystallographic direction of ordered materials is of fundamental significance and of great interest for electronic and photonic applications. However, such orientation control is generally complicated and challenging with regard to inorganic and organic crystalline materials due to the occurrence of uncontrollable dislocations or defects. Achieving uniform lattice orientation in frustrated liquid-crystalline phases, like cubic blue phases, is a formidable task. Taming and tailoring the ordering of such soft, cubic lattices along predetermined or desired directions, and even imparting a prescribed pattern on lattice orientation, are more challenging, due to the entropy-domination attribute of soft matter. Herein, we disclose a facile way to realize designed micropatterning of a crystallographic direction of a soft, cubic liquid-crystal superstructure, exhibiting an alternate uniform and random orientation of the lattice crystallographic direction enabled by a photoalignment technique. Because of the rewritable trait of the photoalignment film, the pattern can be erased and rewritten on-demand by light. Such an oriented soft lattice sensitively responds to various external stimuli such as temperature, electric field, and light irradiation. Furthermore, advanced reflective photonic applications are achieved based on the patterned crystallographic orientation of the cubic blue phase, soft lattice.

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Surface-assisted photoalignment in dye-doped liquid-crystal films

Cited by 69 publications

References 12 publications

Determination of polar anchoring energy of dye-doped liquid crystals by measuring capacitance

Determination of polar anchoring energy of dye-doped liquid crystals by measuring capacitance

Photo-Alignment Technology

Light‐Patterned Crystallographic Direction of a Self‐Organized 3D Soft Photonic Crystal

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