A display device according to an embodiment of the present disclosure includes a see-through area for camera in which a camera module is disposed, a routing area disposed around the see-through area for camera and overlapped by at least one data line and scan line, and a pixel area which includes the see-through area for camera and the routing area and includes a plurality of sub-pixels including an organic light emitting element and a cathode is disposed therein.

An electroluminescent device including a lower substrate; a lower structure including an inorganic multilayer; and an upper encapsulation structure, in which the lower structure includes a display region inside an outline of the inorganic multilayer, and a light transmitting region having a non-through-hole structure having at least a portion surrounded by the display region; the lower structure has an inorganic surface portion surrounding the display and light transmitting regions, the upper encapsulation structure has an inorganic lower surface forming an inorganic-inorganic encapsulation contact region; the electroluminescent device does not have a hole formed through both the lower substrate and the lower structure, a portion of the upper encapsulation structure corresponding to the light transmitting region is not removed, and a portion of the pixel definition layer, the portion corresponding to the light transmitting region, is not present.

In some embodiments, the present disclosure relates to a method of forming a display device, comprising: forming a first reflector electrode and a second reflector electrode over an interconnect structure, wherein the first reflector electrode is laterally separated from the second reflector electrode; depositing a first isolation layer over the first and second reflector electrodes; forming a first masking layer directly overlying the first reflector electrode; depositing a second isolation layer over the first isolation layer and over the first masking layer; forming a second masking layer over the second isolation layer and directly overlying the second reflector electrode; performing a first removal process to remove portions of the first and second isolation layers that do not directly underlie the first or second masking layers; and performing a second removal process to remove the first and second masking layers.

A display device including a display panel having a display area and a non-display area, the non-display area being disposed at a peripheral portion of the display area and having a bending area; an integrated circuit (IC) disposed in the non-display area to drive the display panel; a first layer formed between the display area and the IC and covering the bending area; and a first member covering the IC and the first layer and overlapping with the bending area.

A photoelectronic device includes an active layer containing inorganic particles, and an oxide semiconductor layer containing zinc (Zn), silicon (Si), and oxygen (O), where the oxide semiconductor layer and the active layer are stacked layers. The photoelectronic device further includes a multilayer transparent electrode over or under the active layer, wherein the oxide semiconductor layer serves as a part of the multilayer transparent electrode.

A light-emitting element includes: a light-reflective first electrode; a light-emitting layer above the first electrode; a light-transmissive second electrode above the light-emitting layer; a first light-transmissive layer on the second electrode; and a second light-transmissive layer on the first layer. First optical cavity structure is formed between surface of the first electrode facing the light-emitting layer and surface of the second electrode facing the light-emitting layer. The first optical cavity structure corresponds to, as peak wavelength, first wavelength longer than peak wavelength of light emitted from the light-emitting layer. Second optical cavity structure is formed between the surface of the first electrode facing the light-emitting layer and an interface between the first layer and the second layer. The second optical cavity structure corresponds to, as peak wavelength, second wavelength shorter than the first wavelength. The first and second layers differ in refractive index from each other by 0.3 or greater.

A display substrate includes a base and blue light-emitting units disposed on the base. A blue light-emitting unit includes a first electrode, a first light-emitting layer and a second electrode that are sequentially disposed on the base. Of the first electrode and the second electrode, one electrode is configured to reflect light, and another electrode is configured to transmit light. The first light-emitting layer is configured to emit light having a spectrum whose full width at half maximum is less than or equal to 16 nm.

A display panel includes: a base substrate, a pixel defining layer, light-emitting portions, an electrode layer, a metal repelling portion, and an auxiliary electrode layer. The pixel defining layer includes opening regions and dams. The light-emitting portions are in the opening regions. The electrode layer is on the side of the light-emitting portions facing away from the base substrate. The metal repelling portion is on the side of the electrode layer facing away from the base substrate and in the opening regions. The auxiliary electrode layer is on the side of the pixel defining layer facing away from the base substrate, and includes auxiliary electrode portions located in the region where the dams are located. The auxiliary electrode portions are in contact with third portions of the electrode layer, and the material of the metal repelling portion and the material of the auxiliary electrode layer repel each other.

A transparent display device is provided, which may reduce or minimize loss of light transmittance due to a touch sensor and a touch line and simplify a touch process. The transparent display device includes a substrate provided with a plurality of transmissive areas and a non-transmissive area including a plurality of light emission areas disposed between the transmissive areas adjacent to each other, a plurality of light emitting elements provided in each of the plurality of light emission areas over the substrate, a plurality of touch sensors provided in each of the plurality of transmissive areas over the substrate, a plurality of touch lines provided in the non-transmissive area over the substrate and extended in a first direction, and a plurality of bridge lines provided in the non-transmissive area over the substrate and extended in a second direction to connect at least two touch sensors disposed in the second direction with one of the plurality of the touch lines.

A top-emitting pixel device is disclosed. The pixel device may include a reflective bottom electrode disposed over a substrate, a first charge transport layer disposed over the reflective bottom electrode, an emissive layer disposed over the first charge transport layer, and a second charge transport layer disposed over the emissive layer. Further, the pixel device may include a patterned transparent polymer electrode disposed over the second charge transport layer and extending laterally to cover an emissive area of the top-emitting pixel device, and a patterned auxiliary electrode disposed at least partially over the patterned transparent polymer electrode outside of the emissive area of the top-emitting pixel device to make direct electrical contact with the patterned transparent polymer electrode.