Abstract: A method of fabricating a one-way transparent optical system by which external light is effectively intercepted and internal light passes nearly without loss is provided. The method includes: forming a silver halide on a transparent substrate; aligning a mask in which a predetermined pattern is formed, on the transparent substrate and exposing the silver halide using the mask; developing and fixing the exposed silver halide and forming a plurality of light-absorbing materials on the transparent substrate; and forming protrusion structures having a shape of a convex lens shape for refracting incident light toward a corresponding light-absorbing material of the light-absorbing materials, on the transparent substrate on which the light-absorbing materials are formed.

Abstract: Provided are a photonic crystal type color filter and a reflective liquid crystal display (“LCD”) device having the same. The photonic crystal type color filter includes a substrate, and a photonic crystal disposed on the substrate and having a two-dimensional (2D) grating structure.

Abstract: A surface emitting device using a photonic crystal includes a two-dimensional slab type photonic crystal structure including a first dielectric layer and a second dielectric layer formed on top of the first dielectric layer wherein a plurality of air holes in a two-dimensional lattice pattern are formed on the surface of the second dielectric layer; a light-emitting material layer formed on the inner wall of the air holes; and optical pumping means for irradiating the lateral surface of the photonic crystal structure with light. The surface emitting device shows improved surface emission efficiency and can advantageously emit light close to monochromatic light. Therefore, the surface emitting device can be used to manufacture a surface emitting laser. A method for fabricating the surface emitting device is also disclosed.

Abstract: A method of fabricating a one-way transparent optical system designed to transmit almost 100% of internal light while effectively blocking radiation of external light. The method includes: forming bead-shaped light absorbing elements; dispersing the light absorbing elements over a soft transparent film; and curing the soft transparent film to fix the dispersed light absorbing elements onto the transparent film.

Abstract: Provided are a reflective plate and a display, and a method of controlling a distribution of reflected light. The reflective plate includes a plurality of diffracting grating cells including gratings reflecting incident light, wherein the gratings are arranged at predetermined intervals, and at least one of an arrangement period and an arrangement direction of each of the gratings of the plurality of diffracting grating cells is adjusted to limit a distribution of reflected light.

Abstract: Provided are a method of adjusting a photonic bandgap of a photonic crystal, a method of manufacturing a reflective color filter using the same, and a display device including the reflective color filter. The method of adjusting a photonic bandgap of a photonic crystal includes forming the photonic crystal having a photonic bandgap on a substrate, and changing the photonic bandgap by irradiating light onto the photonic crystal. In addition, the display device includes a backlight, a transflective liquid crystal panel including liquid crystal cells sealed between first and second substrates. Each liquid crystal cell corresponding to a pixel includes a transmissive area and a reflective area. A transmissive color filter is formed on the first substrate, which faces the backlight, and a reflective color filter is formed on each reflective area.

Abstract: Provided are a display pixel using an electroactive polymer and a display apparatus employing the display pixel. The display pixel includes: an electroactive polymer layer, of which shape and/or size is displaced when a voltage is applied thereto; a diffraction grating, of which a pitch and a diffraction angle change according to a displacement of the electroactive polymer layer; and a liquid crystal layer disposed on the diffraction grating and controlling gradation according to a voltage applied thereto.

Abstract: Provided are a reflective unit using an electroactive polymer and a flexible display. The reflective unit includes: an electroactive polymer layer which becomes strained when a voltage is applied thereto by an electrode; a light reflecting unit reflecting external light and having reflecting cells arranged on the electroactive polymer layer to be spaced apart from one another wherein a distance between the reflecting cells is changed according to the strain of the electroactive polymer layer; and a light blocking layer preventing external light from being reflected by the light reflecting unit and having blocking cells arranged over the light reflecting unit to be spaced apart from one another.

Abstract: A laser television including a plurality of lasers for generating different wavelengths of interferential light; a scanner for displaying color images on a screen composed from the light; and a phase diffuser positioned between the lasers and the scanner for diffusing the light from the lasers according to the light's wavelength. The phase diffuser having a boundary surface, through which the light is outputted to the scanner. The boundary surface is slanted with a predetermined angle to regulate the range of diffraction of the light according to the wavelength.

Abstract: A transflective display panel and a display apparatus using the same are provided. The display panel includes a plurality of pixels arranged in a matrix. Each of the pixels includes a plurality of subpixels, and each subpixel within a pixel outputs a different color of light. In addition, each of the subpixels includes a transflective mode region which has a reflection mode region with a diffraction grating and a transmission mode region; a liquid crystal layer which adjusts a transmittance of incident light through electric control; and a sub color filter which transmits light within a wavelength band of the incident light. Because the display panel includes the reflection mode region where the diffraction grating is formed, it can display a high-quality image with good white balance, even while outdoors or under bright illumination.

Abstract: A transistor with a carbon nanotube channel and a method of manufacturing the same. At least two gate electrodes are formed on a gate insulating layer formed on a carbon nanotube channel and are insulated from each other. Thus, the minority carrier may be reduced or prevented from flowing into the carbon nanotube channel. Accordingly, it is possible to reduce or prevent a leakage current that is generated when both the majority carrier and the minority carrier flow into the carbon nanotube channel. Therefore, characteristics of the transistor may not be degraded due to the leakage current.

Abstract: A wire grid polarizer and a method of manufacturing the wire grid polarizer are provided. The wire grid polarizer includes: a substrate; and a plurality of core-shell nano wires arranged on the substrate and including wire cores and polymer shells enclosing the wire cores to a predetermined thickness.

Abstract: An apparatus and method for microstructures of a display device which focus external light toward light-absorption regions to enhance brightness and contrast of the display device. The display device includes a light absorption layer disposed to one side of a light emission layer. The light absorption layer includes light refracting structures and light absorption elements, wherein each of the light absorption elements is positioned in the light refracting structures. The light directing structures substantially direct incident light toward one of the plurality of light absorption elements positioned therein to reduce the reflection of external light.

Abstract: A method of fabricating a one-way transparent optical system by which external light is effectively intercepted and internal light passes nearly without loss is provided. The method includes: forming a photoresist on an upper surface of a transparent substrate; heating and carbonizing the photoresist to form a black body layer; patterning the black body layer to form a plurality of light-absorbing materials on the transparent substrate; and forming protrusion structures having a shape of a convex lens shape for refracting incident light toward a corresponding light-absorbing material of the light-absorbing materials, on the transparent substrate on which the light-absorbing materials are formed.

Abstract: A surface emitting device using a photonic crystal includes: a two-dimensional slab type photonic crystal structure including a first dielectric layer and a second dielectric layer formed on top of the first dielectric layer wherein a plurality of air holes in a two-dimensional lattice pattern are formed on the surface of the second dielectric layer; a light-emitting material layer formed on the inner wall of the air holes; and optical pumping means for irradiating the lateral surface of the photonic crystal structure with light. The surface emitting device shows improved surface emission efficiency and can advantageously emit light close to monochromatic light. Therefore, the surface emitting device can be used to manufacture a surface emitting laser. A method for fabricating the surface emitting device is also disclosed.

Abstract: A one-way transparent optical system and a flat panel display having the same are provided. The one-way transparent optical system includes a transparent substrate and an external light blocking layer. The external light block layer includes: first light reflecting layers, first and second light reflecting layers, transmitting windows, and first and second light absorbing layers. The first light reflecting layers are formed on and inclined toward the transparent substrate. The second light reflecting layers are spaced a predetermined distance from the first light reflecting layers. The first and second light reflecting layers are alternately arranged on the transparent substrate. The transmitting windows are formed in the upper and lower portions of the spaces between the first and second light reflecting layers. The first and second light absorbing layers respectively formed on the first and second light reflecting layers.

Abstract: A method of fabricating a one-way transparent optical system by which external light is effectively intercepted and internal light passes nearly without loss is provided. The method includes: forming a silver halide on a transparent substrate; aligning a mask in which a predetermined pattern is formed, on the transparent substrate and exposing the silver halide using the mask; developing and fixing the exposed silver halide and forming a plurality of light-absorbing materials on the transparent substrate; and forming protrusion structures having a shape of a convex lens shape for refracting incident light toward a corresponding light-absorbing material of the light-absorbing materials, on the transparent substrate on which the light-absorbing materials are formed.

Abstract: A method of fabricating a one-way transparent optical system by which external light is effectively intercepted and internal light passes nearly without loss is provided. The method includes: forming a photoresist on an upper surface of a transparent substrate; heating and carbonizing the photoresist to form a black body layer; patterning the black body layer to form a plurality of light-absorbing materials on the transparent substrate; and forming protrusion structures having a shape of a convex lens shape for refracting incident light toward a corresponding light-absorbing material of the light-absorbing materials, on the transparent substrate on which the light-absorbing materials are formed.

Abstract: A method of fabricating a one-way transparent optical system designed to transmit almost 100% of internal light while effectively blocking radiation of external light. The method includes: forming bead-shaped light absorbing elements; dispersing the light absorbing elements over a soft transparent film; and curing the soft transparent film to fix the dispersed light absorbing elements onto the transparent film.

Abstract: A memory device using vertical nanotubes includes an array of first electrodes arranged in strips in a first direction, a dielectric layer deposited on the array of first electrodes, the dielectric layer having a plurality of holes arranged therein, an array of nanotubes for emitting electrons, the array of nanotubes contacting the array of first electrodes and vertically growing through the plurality of holes in the dielectric layer, an array of second electrodes arranged in strips in a second direction on the dielectric layer, the array of second electrodes contacting the array of nanotubes, wherein the second direction is perpendicular to the first direction, a memory cell positioned on the array of second electrodes for trapping electrons emitted from the array of nanotubes, and a gate electrode deposited on an upper surface of the memory cell for forming an electric field around the array of nanotubes.