A preparation method of a light-emitting device includes forming a composite transition layer between a cathode and a quantum dot light-emitting layer and forming an anode on a surface of the quantum dot light-emitting layer away from the cathode. The composite transition layer includes a first transition layer, a second transition layer, and a third transition layer. The first transition layer is arranged on one side close to the cathode and includes a metal halide. The second transition layer is arranged on a surface of the first transition layer away from the cathode and includes a hydrogen halide. The third transition layer is arranged on a surface of the second transition layer away from the first transition layer and includes an ester compound.

Provided are a display substrate, a preparation method thereof, and a display apparatus. A portion of a pixel definition layer that is in contact with a light-emitting functional layer is configured to have the performance of switching between hydrophilicity and hydrophobicity when an external condition changes. When film layers of the light-emitting functional layer are formed, due to the inconsistent hydrophilicity or hydrophobicity of the film layers of the light-emitting functional layer, when a hydrophilic light-emitting functional layer is formed, the pixel definition layer switches, under processing via the external condition, the portion of the pixel definition layer that is in contact with the light-emitting functional layer to be hydrophobic, and when a hydrophobic light-emitting functional layer is formed, the pixel definition layer switches, under processing via the external condition, the portion of the pixel definition layer that is in contact with the light-emitting functional layer to be hydrophilic.

The disclosure relates to a quantum dot light-emitting diode and a fabricating method thereof. The quantum dot light-emitting diode includes a quantum dot layer and an electron transport layer formed on the quantum dot layer. A surface of a side of the quantum dot layer close to the electron transport layer bonds to an ester substance.

The present disclosure relates to a display device. According to an embodiment of the present disclosure, a display device includes a supporter including a plurality of segments disposed to be spaced apart from each other and defining a plurality of holes between the plurality of segments, and a display panel disposed on the supporter. The display panel includes: an active element layer including a light emitting element and a thin film transistor for driving the light emitting element, an encapsulation layer disposed on the active element layer, a plurality of stress dispersion pattern disposed on the encapsulation layer to overlap the plurality of holes in a thickness direction, and an insulating layer disposed on the plurality of stress dispersion pattern and filling a plurality of holes defined between the plurality of stress dispersion pattern.

A light-emitting diode and a preparation method of the light-emitting diode are provided in the present application. The light-emitting diode includes an anode and a cathode which are arranged opposite to each other, a luminescent layer arranged between the anode and the cathode, an electron transport layer arranged between the cathode and the luminescent layer, and a composite film arranged between the cathode and the electron transport layer. Where the composite film includes an aluminum oxide film arranged adjacent to the electron transport layer, and a nano metal oxide film or a silicon nitride film arranged away from the electron transport layer. The light-emitting diode according to the present application may block water and oxygen from infiltrating into it effectively, so that a poor stability of the light-emitting diode device in a water-oxygen environment is improved.

The display substrate includes: a first electrode located in a first display region and a second electrode located in a second display region; a first light emitting layer located in the first display region and a second light emitting layer located in the second display region; and a third electrode located in the first display region and a fourth electrode located in the second display region. By optimizing patterned design of the third electrode, a first electrode wiring mode in the first display region is optimized, so that a display effect in the first display region is improved, glare interference is reduced, the transmittance of the first display region is optimized and improved, and a photographing effect of an under-screen camera configured in the first display region is ensured.

A method of manufacturing an inorganic oxide particle having an inorganic oxide core and a hydroxyl group bonded to a surface thereof includes: preparing a first composition including an inorganic oxide core precursor and a proton supply compound; and heating the first composition. Additional embodiments provide a method of manufacturing an inorganic oxide layer including an inorganic oxide particle manufactured by the method, and a light-emitting device including an inorganic oxide layer manufactured by the method.

A display panel includes light-emitting electrodes respectively disposed in first to third emission areas, first intermediate layers respectively disposed in the first to third emission areas and respectively overlapping the light-emitting electrodes, a bank layer covering an edge of each of the first intermediate layers and including openings respectively overlapping the first intermediate layers, a counter electrode disposed on the bank layer and covering the light-emitting electrodes, quantum dot light-emitting layers arranged below the counter electrode and respectively disposed in the first to third emission areas, and a second intermediate layer between the first intermediate layer in the first emission area and the quantum dot light-emitting layer in the first emission area. The second intermediate layer is disposed in an opening of the bank layer corresponding to the first emission area, the opening being one of the openings of the bank layer.

A display device includes a substrate, an emission structure disposed on the substrate, a first refraction pattern disposed on the emission structure, a second refraction pattern disposed on the first refraction pattern and covering the first refraction pattern, where the second refraction pattern includes an inorganic material, and a third refraction pattern disposed on the second refraction pattern and having a refractive index less than a refractive index of the first refraction pattern.

A display device includes a base layer, a first electrode on the base layer, a pixel-defining layer in which an opening exposing an upper surface of the first electrode is defined, a protective layer overlapping the pixel-defining layer and between the pixel-defining layer and the first electrode, a functional layer on the first electrode in the opening, an auxiliary electrode on an upper surface of the pixel-defining layer, and a second electrode on the functional layer and the auxiliary electrode.