Optically Rewritable Liquid Crystal Displays: Characteristics and Performance

Chigrinov, Vladimir G.; Kudreyko, Aleksey; Подгорнов, Ф. В.

doi:10.3390/cryst11091053

Cited by 5 publications

(1 citation statement)

References 23 publications

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“…Thus, optically rewritable electronic paper (ORW e-paper) is an electrode-free and optically addressed device with a grayscale capability, wide viewing angles and a contrast ratio of about 10:1. All these properties have been widely discussed in our previous reviews [7,8] and studies [9,10]. Further investigation of ORW e-paper has shown that it can play the role as an element base for advanced light-driven applications, which include security films [11], methods of 3D visualization [12,13], color reflectors [14] and transparent devices [15].…”

Section: Introductionmentioning

confidence: 95%

Photosensitive Alignment: Advanced Electronic Paper-Based Devices

2022

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In this review we describe the reversible photoalignment effect imposed on the director in nematic liquid crystals that provides an approach for fabrication of advanced optically addressed devices. Several new concepts have been developed to render photosensitive materials during the past decade. Functional soft azo dye compounds exhibiting distinct functionalities in response to polarized light are highly desirable for fabrication of optically rewritable electronic paper. An optically rewritable element base using simple and inexpensive materials can potentially enable the development of novel environmentally friendly, paper-like gadgets with improved functionality over regular electronic paper. We argue that an optically rewritable technique is relevant for some applications, where conventional paper might be irrelevant. In particular, we have tested and discussed several techniques of color and 3D image formation. This strategy for fabrication of novel devices offers versatile methods for visualization. We also show that the intensity modulation of the irradiation light has a potential to generate improved grayscale visualization. This principle is based on the statistical distribution control of photosensitive azo dye molecules, driven by the incident polarized light. Additionally, we discuss the functional characteristics of the developed prototypes.

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Section: Introductionmentioning

confidence: 95%

Photosensitive Alignment: Advanced Electronic Paper-Based Devices

2022

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The anchoring effect and cooperative interactions in 5CB/CNC molecular films

Bielejewska,

Hertmanowski

2024

Liquid Crystals

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Thermal imprint of wide-angle viewing bi-stable cholesteric liquid crystal displays

et al. 2022

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A thermal-imprint addressable and electrically erasable bi-stable cholesteric liquid crystal (CLC) display with a wide viewing angle is demonstrated. The proposed device with a multi-domain planar state is realized by filling a negative CLC in a vertical-alignment cell. The thermal-imprint method is introduced to restore the CLC from a reflective state (multi-domain planar state) to a translucent state (focal-conic state) to display images, and an electric field is used to erase the device back to totally reflective mode. This CLC display is bi-stable and does not require a complex driving circuit. Together with the features of a large viewing angle and less color shift, this device shows great potential for update-on-demand applications.

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Optically Rewritable Liquid Crystal Displays: Characteristics and Performance

Cited by 5 publications

References 23 publications

Photosensitive Alignment: Advanced Electronic Paper-Based Devices

Photosensitive Alignment: Advanced Electronic Paper-Based Devices

The anchoring effect and cooperative interactions in 5CB/CNC molecular films

Thermal imprint of wide-angle viewing bi-stable cholesteric liquid crystal displays

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