According to the present disclosure, an organic optoelectronic component provides with a first electrode, an organic functional layer structure above the first electrode, a second electrode above the organic functional layer structure, at least one contact section for electrically contacting the organic optoelectronic component, and an electrically conductive elastomer connector which is arranged above the contact section and is electrically connected to the contact section. The contact section is electrically connected to one of the electrodes.

An electronic component includes a connection carrier having a cover surface, a first electric connection point and a second electric connection point, and an organic active area. A first electrode interconnects in an electrically conductive manner the active area and the first electric connection point. An encapsulation layer protects the active area against humidity and atmospheric gases. The electronic component can be contacted from the outside by the electric connection points and the encapsulation layer is in direct contact, in places, with the connection carrier.

The present invention relates to an organic light-emitting element and a production method thereof. Specifically, the present invention relates to an organic light-emitting element, which has excellent productivity during mass production thereof and may allow simplification of vapor deposition equipment, and the like, and a production method thereof.

A method for producing a bent organic light-emitting diode and a bent organic light-emitting diode are disclosed. In an embodiment the method includes providing an emitter unit having an organic layer sequence for generating radiation, providing at least one electrical connection piece, bending the at least one connection piece and the emitter unit into a curved shape and subsequently mechanically fixedly and permanently connecting the at least one connection piece to the emitter unit so that the curved shape is permanently maintained.

The organic light-emitting diode (1) has a first electrode (21) with a first electric conductivity and a second electrode (22) with a second lower electric conductivity. An organic layer stack (4) for generating light is located between the electrodes (21, 22). The light-emitting diode (1) further comprises a current distribution layer (3) with a third high electric conductivity. When seen in a plan view, multiple contact regions (33) are located outside of an outer contour line (40) of the layer stack (4). The second electrode (22) and the current distribution layer (3) contact each other in the contact regions (33). In a current blocking region (34), the current distribution layer (3) is located entirely within the contour line (40) such that the second electrode (22) is electrically disconnected from the current distribution layer (3). The luminous intensity of a lighting surface (11) of the light-emitting diode (1) is preferably set in a controlled manner via the distribution of the contact regions (33) and the current blocking regions (34).

The present invention provides an organic optoelectronic device and a method for manufacturing the same, in which laser scanning is used to form the electrical connection between the second electrode layer and the contact electrode layer. The present invention can effectively decrease the frequency of replacement of metal masks, significantly shorten the time required for replacing the metal masks, and reduce the down time due to the replacement of metal masks. In addition, the organic optoelectronic device can have a large active area due to the narrow border of the electrical connection formed by the laser scanning.

An LED device comprises a substrate and a stack of layers defining an LED component and including an electroluminescent layer. A capacitive structure is formed on top of the stack of layers. The area of the defined capacitor encodes information concerning the electrical characteristics of the LED component.

The invention relates to a layered structure (1) of an apparatus that luminesces by means of organic luminescence, which consists of at least two layers (2, 3) of transparent, semiconductive fibers as a substrate and an electrode, as well as a layer (5) disposed between adjacent layers (2, 3), composed of a photoactive polymer, in which layer, in interaction with the adjacent layers (2, 3) of transparent, semiconductive fibers, an organic luminescence (7) can be brought about. Furthermore, methods for the production and for the operation of corresponding layered structures, and a luminescent apparatus formed from them, are indicated.

The present application relates to a method of preparing a metal pattern having a 3D structure, a metal pattern laminate, and use of the metal pattern laminate. According to the method of preparing a metal pattern, the metal pattern having a 3D structure can be effectively formed on a receptor. Especially, the metal pattern having a 3D structure can also be effectively and rapidly transferred to a surface of the receptor, such as, a flexible substrate, to which the metal pattern is not easily transferred. The metal pattern laminate prepared using the method can, for example, be usefully used for metal layers of flexible electronic devices or metal interconnection lines.

A display device includes a substrate which includes a display area and a non-display area, a pixel unit which is provided in the display area and includes a plurality of pixel columns, and data lines which are respectively connected to the pixel columns and apply data signals to the pixel columns. The non-display area includes a fanout area, a bent area, and a pad area which are sequentially arranged. The respective data lines are disposed on different layers in the fanout area and the pad area. A resulting display device can reduce resistance deviation between data signals in a first data line and a second data line, thereby reducing vertical line defects