Hu Dou scite author profile

A liquid crystal (LC) lens array with high light control power and a large aperture using a composited alignment layer is proposed. In our design, the alignment layer is not only used for getting a uniform arrangement of LC molecule, but also for getting a lens-like refractive index distribution in the LC layer when a voltage is applied. Through simple technology processes, a tunable focal length LC lens array with a millimeter scale diameter can be achieved. Furthermore, the maximum phase difference of the proposed LC lens array can achieve 105.38π. So, the proposed LC lens array has a high light control power.

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A transflective blue-phase liquid crystal display with alternate electrodes

Chu

Dou

Song

et al. 2017

Liquid Crystals

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A transflective polymer-stabilised blue-phase liquid display with partitioned wall-shaped electrodes

et al. 2018

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Electrically Tunable-Focusing Liquid Crystal Microlens Array with Simple Electrode

et al. 2019

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An electrically tunable-focusing liquid crystal (LC) microlens array exhibiting a wide-range tunable focal length is proposed. The lower substrate has strip indium tin oxide (ITO) electrodes, the upper substrate has periodic ITO electrodes with a certain gap coated on the inner surface., and an LC microlens is generated between the two strip electrodes. For each LC microlens, the gap between the top planar electrodes is directly above the center of the microlens. Unlike the conventional LC lens, the individual LC microlens is not coated with ITO electrodes on the central part of its upper and lower substrates, which helps to maintain the LC’s horizontal orientation. In the voltage-off state, the focal length of the microlens array is infinity because of the homogeneous LC alignment. At a given operating voltage, an ideal gradient refractive index distribution is induced over the homogeneous LC layer, which leads to the focusing effect. The simulation result shows that the focal length of the LC microlens could be gradually drawn to 0.381 mm with a change of voltage.

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Single electro-optic curve for RGB colours in blue-phase liquid crystal display

Guo

et al. 2018

Liquid Crystals

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Transflective blue-phase liquid crystal display with dielectric protrusion

et al. 2019

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Blue-phase liquid crystal display with insulating protrusion

et al. 2018

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A controllable viewing angle optical film using micro prisms filled with liquid crystal

Dou

Chen

et al. 2021

Liquid Crystals

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Hu Dou

Large aperture liquid crystal lens array using a composited alignment layer

A transflective blue-phase liquid crystal display with alternate electrodes

A transflective polymer-stabilised blue-phase liquid display with partitioned wall-shaped electrodes

Electrically Tunable-Focusing Liquid Crystal Microlens Array with Simple Electrode

Single electro-optic curve for RGB colours in blue-phase liquid crystal display

Transflective blue-phase liquid crystal display with dielectric protrusion

Blue-phase liquid crystal display with insulating protrusion

A controllable viewing angle optical film using micro prisms filled with liquid crystal

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