A laminated curved article [102] comprising a first substrate [102a] consisting an outer face and a ceramic masked [104] inner face along the periphery, one or more interlayers [102c] disposed on the inner face of the first substrate [102a], a second substrate [102b] disposed on the interlayer [102c] and one or more electroluminescent devices [116] connected to connector element [126] and provided in the ceramic masked [104] inner face of the first substrate [102a] and the second substrate [102b]. The one or more electroluminescent devices [116] comprising a dielectric layer [116a] disposed on a luminescence layer [116b], wherein both the dielectric layer [116a] and luminescence layer [116b] are sandwiched together by a multilayer consisting of a conductive layer [116c], an insulating layer [116d] and a protective layer [116e].

A device comprising a light emitting diode (LED) substrate, and a meta-molecule wavelength converting layer positioned within an emitted light path from the LED substrate, the a meta-molecule wavelength converting layer including a plurality of nanoparticles, the plurality of nanoparticles configured to increase a light path length in the wavelength converting layer.

In a light-emitting device, a first electrode, a light-emitting layer, and a second electrode are disposed in the order recited. Moreover, a charge transport layer is disposed between the first electrode and the light-emitting layer and/or between the second electrode and the light-emitting layer. A third electrode at least partly overlaps the light-emitting layer. Moreover, the third electrode is disposed between the charge transport layer and the light-emitting layer.

Bulk assemblies are provided, which may have desirable photoluminescence quantum efficiencies. The bulk assemblies may include two or more metal halides, and a wide band gap organic network. The wide band gap organic network may include organic cations. The metal halides may be disposed in the wide band gap organic network. Light emitting composite materials also are provided.

An electro-luminescent film including a substrate and anisotropic semiconductor nanoparticles distributed on the substrate according to a periodic pattern. The semiconductor nanoparticles have an aspect ratio greater than 1.5, and the repetition unit of the pattern has a smallest dimension of less than 500 micrometer and includes at least one pixel. Also, a process for the manufacture of the electro-luminescent film, and a light emitting device that includes the electro-luminescent film.

A method for manufacturing an inorganic thin film electroluminescent display element comprises forming a layer structure, said forming the layer structure comprising forming a first dielectric layer (11); forming a luminescent layer (12), comprising manganese doped zinc sulfide ZnS:Mn, on the first dielectric layer, and forming a second dielectric layer (13) on the luminescent layer. Each of the first and the second dielectric layers are formed so as to comprise nanolaminate with alternating aluminum oxide Al.sub.2O.sub.3 and zirconium oxide ZrO.sub.2 sub-layers.

A property prediction system is provided. An input portion, a processing portion, an arithmetic portion, and an output portion are included; the input portion has a function of supplying the structure of a light-emitting device or the properties of the light-emitting device; the processing portion has a function of generating a learning data set or data that is used for property prediction and a function of quantifying the molecular structure of an organic compound; the arithmetic portion has a function of performing supervised learning on the basis of the learning data set and a function of making an inference of the properties of the light-emitting device from the data on the basis of the learning result of the supervised learning; and the output portion has a function of providing the result of the inference. Thus, the properties of the light-emitting device including a layer containing an organic compound are predicted.

The present application discloses a light-emitting component and a display apparatus. The light-emitting component includes a first diffusion layer, a first prism sheet disposed below the first diffusion layer; a second prism sheet disposed below the first prism sheet; a second diffusion layer disposed below the second prism sheet; a flexible substrate disposed below the second diffusion layer; a second substrate attached to the flexible substrate; an emission layer disposed between the second diffusion layer and the flexible substrate; the emission layer is integrated on the flexible substrate; the emission layer includes a photoluminescence layer and an electroluminescent layer; the photoluminescence layer is disposed between the second diffusion layer and the flexible substrate; and the electroluminescent layer is disposed between the photoluminescence layer and the flexible substrate.

A patterning method of a quantum dot layer, a quantum dot layer pattern, a quantum dot device, a manufacturing method of the quantum dot device, and a display apparatus are provided. The patterning method of the quantum dot layer includes: forming a quantum dot layer, in which the quantum dot layer includes quantum dots and a photoinitiator; irradiating a preset portion of the quantum dot layer by light having a preset wavelength to quench the quantum dots in the preset portion and form a patterned quantum dot layer.

Luminescent microspheres and a preparation method thereof are disclosed. The preparation method includes: 1) preparing cadmium oxide-doped silica microspheres; 2) adding the silica microspheres to a mixed solution of octadecene/oleic acid or trioctylamine (TOA)/oleic acid, and heating a resulting mixture to a boiling point so that the microspheres swell at high temperature and the oleic acid penetrates into the microspheres to react with CdO to obtain an organic cadmium-adsorbed silica suspension; and 3) adding a selenium precursor to the obtained organic cadmium-adsorbed silica suspension to obtain the luminescent microspheres, where, the selenium precursor reacts with the adsorbed organic cadmium to form CdSe. The luminescent microspheres provided in the present disclosure have high fluorescence efficiency and prominent stability, require no barrier materials such as barrier films for protection, and can be directly used for light conversion materials with high color gamut such as luminescent films, luminescent plates, Mini-LEDs, and Micro-LEDs.