Abstract: A fabricating method of a conductive substrate including the following steps is provided. A substrate is provided. A barrier layer having a first roughened surface is formed on the substrate by an atmospheric pressure plasma process, wherein the surface roughness (Ra) of the first roughened surface formed by the atmospheric pressure plasma process is between 10 nanometers (nm) and 100 nm. A first electrode layer is formed on the first roughened surface of the barrier layer by a vacuum sputter process, wherein a second roughened surface with the surface roughness (Ra) between 10 nm and 100 nm is formed on a surface of the first electrode layer. Furthermore, a photoelectric conversion layer is formed on the second roughened surface of the first electrode layer. A second electrode layer is formed on the photoelectric conversion layer. A solar cell and a conductive substrate are also provided.

Abstract: The present invention generally relates to a scheme for making color filters on the basis of laser printing, and particularly to a scheme exploiting digital systems (or logic processor) and laser printer to make color filters in a simple, economical, and swift way, and being capable of dynamically adapting to various demanded specifications. The scheme for making color filters according to the present invention mainly comprises the steps: defining a dot matrix according to the demanded specifications; converting the dot matrix into an image signal; and executing a laser printing process to print, according to the image signal, an image of the dot matrix on a transparent plate.

Abstract: The present invention relates to a single component performing light polarization and color filtering, and to a production process making the component. The component comprises a polarization plate with photo resistant material of three primary colors distributed at a plurality of dot locations on one of its surface, and with light absorbing material disposed between any adjacent two of the dot locations. The production process comprises the steps of forming a dot matrix on a surface of the polarization plate and filling photo resistant material onto the dots of the dot matrix.

Abstract: An encapsulation method of organic electroluminscence device is provided. An organic electroluminescent device is formed on an indium-tin-oxide glass substrate. A metal electrode is formed on the organic electroluminescent device. The organic electroluminescent device is encapsulated by a nitride layer or a carbide layer formed by using segmental sputtering at a low temperature. The substrate is soldered on a metal plate and covered by a metal cap.

Abstract: A method for fabricating a full-color organic electro-luminescent device starts with forming an indium tin oxide (ITO) layer on a glass substrate, and then forming a blue-light emitting layer on the ITO layer. By irradiating predetermined portions of the blue-light emitting layer with certain light sources, pixels that emit different light colors are formed on the irradiated portions of the blue-light emitting layer. An electrode layer is then formed on the corresponding pixels, wherein the electrode layer is further covered by a protection layer. During the operation of the full-color OEL device of the invention, a driving voltage is applied on the ITO layer, the anode, and the electrode layer, the cathode.

Abstract: A plasma-polymerized anti-fogging film is formed by polymerization-depositing a high molecular polymerized DMDAS film on a substrate to provide the substrate surface with anti-fogging capability. The plasma polymerization deposition process is performed by using diacetoxy silane monomer that contains bi-carboxylate O.dbd.C--O-- functional group as the reactant monomer with an introduction of a suitable amount of oxygen to cause the polymerization reaction. The reactant monomer and the oxygen are introduced into a vacuum deposition apparatus and a high energy plasma is generated between electrodes of the vacuum deposition apparatus to cause the polymerization reaction on the substrate to form thereon the high molecular polymerized DMDAS anti-fogging film.

Abstract: A foldable screen display for displaying screen images is disclosed which comprises: (a) at least two sub-displays; (b) a hinging member for pivotally connecting the sub-displays together on a side-by-side manner; (c) a magnifying optical element provided on top of each of the sub-displays, the magnifying optical element providing a magnifying power of between about 1.05 and about 1.3 so as to cause images displayed on the sub-displays to be perceived by a user as if they were from a single display; and (d) a membrane covering both of the sub-displays and the hinging member, the membrane being made of a transparent and resilient material. In a preferred embodiment, the magnifying optical element is a zone plate type magnifying optical element and is constructed to provide a magnifying power approximately equalling to one plus the ratio between the width of the hinging member and the width of sub-display.