The subject invention provides a capacitor-drive electroluminescent display, which includes a display substrate, row and column electrodes that are deposited on the substrate, and the light-emitting pixel that is electrically connected to (and in between) the row and column electrodes, wherein the light-emitting pixel includes a light-emitting device, a drive capacitor, and a charging switch; wherein, the light-emitting device and the drive capacitor is electrically connected in parallel, which is then electrically connected to the charging switch; wherein, the row or column electrode has a light-emitting windows for installation of the electroluminescent devices. Meanwhile, the subject invention also provides a method for producing the capacitor-drive electroluminescent display.

A transparent display apparatus is provided that is constructed to transmit or block a light of images selectively according to a supply of electric power to a conventional transparent organic light emitting diode. The transparent display apparatus includes a transparent organic light emitting diode having a glass substrate, a transparent anode, a hole transport layer, an emitting layer, an electron transport layer and a transparent cathode. The transparent display apparatus includes an insulating layer stacked on the transparent cathode, and first and second transparent ITOs stacked on the insulating layer to deliver electromotive force onto an entire surface and to transmit or block the light of images according to the on/off state of a power source. The transparent display apparatus also includes an electro chromic layer provided between the first and the second transparent ITOs and including transparent and colorless chemicals. The electro chromic layer forms a color through oxidation-reduction reaction of the chemicals according to the on/off state of the power source to absorb or block the light of images. The transparent display apparatus further includes a substrate stacked on the second transparent ITO.

Provided is a light-emitting device including a pair of substrates each of which includes a conductive layer, a light-emitting element, disposed between the pair of substrates, which includes a first electrode and a second electrode facing each other, and a resin layer, containing conductive particles, which fills a space between the substrates and electrically connects the conductive layers of the substrates to the first and second electrodes of the light-emitting element.

An object of the invention is to provide a novel laminate and a novel image display device which have both of a gas barrier function and a circular polarization conversion function and have a reduced thickness as compared to those in the related art. A laminate of the invention has a substrate, an organic layer A, an inorganic layer B, and an organic layer B in this order, and at least one of the organic layer A or the organic layer B contains a liquid crystal compound.

A thin film transistor array panel includes a substrate and a thin film transistor disposed on a surface of the substrate. The thin film transistor includes a semiconductor, a source electrode, and a drain electrode that are disposed on a same layer as one another. The semiconductor is between the source electrode and the drain electrode. The thin film transistor array panel further includes a buffer layer disposed between the semiconductor and the substrate and including an inorganic insulating material. The first edge of the buffer layer is substantially parallel to an adjacent edge of the semiconductor, a second edge of the buffer layer is substantially parallel to an adjacent edge of the source electrode, and a third edge of the buffer layer is substantially parallel to an adjacent edge of the drain electrode.

A source to facilitate precise vapor deposition in processes to obtain organic light emitting diodes (OLEDs) in a display panel, includes forming a plurality of grooves on a first substrate; in filling organic light emitting materials into the grooves and providing a second substrate to receive the vaporized organic light emitting materials. The first substrate is aligned with the second substrate and the first substrate is heated to vaporize the organic light emitting materials in the grooves. The vapor deposition regions of the second substrate form an organic light emitting material layer after the deposition, the layer can then be used in an OLED display panel. The shadow effect is greatly reduced, a method for the procedure is also disclosed.

Embodiments of the present disclosure describe light emitting displays having a light emitter layer that includes an array of light emitters and a wafer having a driving circuit coupled with the light emitter layer, computing devices incorporating the light emitting displays, methods for formation of the light emitting displays, and associated configurations. A light emitting display may include a light emitter layer that includes an array of light emitters and a wafer coupled with the light emitter layer, where the wafer includes a driving circuit formed thereon to drive the light emitters. Other embodiments may be described and/or claimed.

The present disclosure provides a display device and a method for manufacturing the same. The display device includes a first substrate, a second substrate and at least one flexible printed circuit. The first substrate is opposite to the second substrate. A first end of the flexible printed circuit is attached onto at least one side of the first substrate, and a second end of the flexible printed circuit is attached onto the second substrate. A slope structure is arranged at an edge of the first substrate at a side thereof where the first end of the flexible printed circuit is attached.

The present disclosure provides a flexible substrate material, a method of manufacturing a flexible display panel substrate and a flexible display panel. The flexible substrate material includes a polyimide substrate and a carbon nanotube reinforcement mixed in the polyimide substrate. The method of manufacturing a flexible display substrate provided by the present disclosure provides the flexible display panel substrate with better abilities of curl deformation resistance and crack resistance by introducing the carbon nanotube reinforcement phase into the synthesis process of the phase of the polyimide substrate. The flexible display panel substrate provided by the present disclosure has more excellent quality due to the flexible substrate with the abilities of curl deformation resistance and crack resistance.

A foldable display panel, including an active area and a non-active area disposed around the active area, and a deformation layer disposed in the non-active area of the display panel. A material of the deformation layer includes a force-strained material configured to detect a degree of deformation and a cracking defect of the display panel according to a luminous color and brightness of the force-strained material.