An electronic device including a first electronic component including a first pad unit, a second electronic component electrically connected to the first electronic component, the second electronic component including a second pad unit connected to the first pad unit, and a conductive adhesion film that couples the first pad unit to the second pad unit. The conductive adhesion film includes an adhesion resin layer, a conductive ball dispersed in the adhesion resin layer, and a curing agent capsule dispersed in the adhesion resin layer, the curing agent capsule including a curing initiator and a tube that seals the curing initiator.

In various embodiments, a conversion device is provided. The conversion device may include a phosphor element made of a phosphor element material for converting pump radiation into conversion radiation; and a scattering element embodied as a volume scatterer. The scattering element is arranged in direct optical contact with the phosphor element in order to be transilluminated by the conversion radiation. The phosphor element material is present in monocrystalline form in the phosphor element over a volume of at least 1×10.sup.−2 mm.sup.3.

An organic electroluminescence device according to the present invention includes: a base material having a top surface on which a recess is provided; a reflective layer provided along at least a surface of the recess; a filling layer filled in the recess via the reflective layer, the filling layer having light transmissivity; a first electrode provided at least on an upper layer side of the filling layer, the first electrode having light transmissivity; an organic layer provided on an upper layer side of the first electrode, the organic layer including at least a light emitting layer; and a second electrode provided on an upper layer side of the organic layer, the second electrode having light transmissivity. The second electrode has a reflectance of 70% or less.

A light emission device includes an organic EL panel and a molding resin. In the organic EL panel, an organic EL light emission portion is formed on a substrate. The organic EL panel is flexible. The molding resin shapes the organic EL panel so that the organic EL panel is in a curved state.

An organic EL display panel includes: a first pixel electrode and a red organic light-emitting layer sequentially disposed in red subpixel region; a second pixel electrode and a green organic light-emitting layer sequentially disposed in green subpixel region; a third pixel electrode and a first blue organic light-emitting layer sequentially disposed in blue subpixel region; a charge generation layer disposed above the red, green, and first blue light-emitting layers; a second blue organic light-emitting layer disposed on the charge generation layer in the entire subpixel regions; a counter electrode disposed above the second blue light-emitting layer in the entire subpixels regions; a first light conversion layer disposed above the second blue light-emitting layer in the red subpixel region, and converts blue light to red light; and a second light conversion layer disposed above the second blue light-emitting layer in the green subpixel region, and converts blue light to green light.

A flexible display includes surfaces that can be folded, bent, or curved into a workstation, kiosk, or other configuration. The surfaces in the flexible display can be bent or folded to provide viewing surfaces in various planes. A controller can configure the display to provide selected functions on the various defined surfaces. A number of display stands for mounting the displays are also disclosed.

A quantum dot electronic device comprises a first encapsulation layer, a first electrode disposed on the first encapsulation layer, a quantum dot pattern disposed on the first electrode, a second electrode disposed on the quantum dot pattern and a second encapsulation layer disposed on the second electrode. The quantum dot pattern may be formed by an intaglio transfer printing method, where the method comprises forming a quantum dot layer on a donor substrate, picking up the quantum dot layer using a stamp, putting the quantum dot layer into contact with an intaglio substrate using the stamp and separating the stamp from the intaglio substrate. Using the quantum dot transfer printing method, a subminiature quantum dot pattern can be transferred at a high transfer rate. Accordingly, a highly integrated quantum dot electronic device exhibiting excellent performance and a high integrated quantum dot light emitting device with an ultrathin film can be realized.

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 fluorescent film including a substrate and semiconductor nanoparticles distributed on the substrate according to a periodic pattern. The semiconductor nanoparticles have a longest dimension greater than 25 nanometers or an aspect ratio greater than 1.5, and the repetition unit of the pattern has a smallest dimension of less than 500 micrometers and comprises at least two pixels. Also, a process of manufacturing the fluorescent film.

A quantum dot display substrate, a method for manufacturing a quantum dot display substrate and a display device are provided. The method includes: forming a carrier transport layer on a substrate; forming a quantum dot layer emitting light of a corresponding color in each of the pixel regions, and forming the quantum dot layer includes: forming a pattern-defining layer on the carrier transport layer, the pattern-defining layer exposes a portion of the carrier transport layer in the pixel region and covers remaining portion of the carrier transport layer, hydrophilicity and hydrophobicity of the pattern-defining layer are respectively opposite to those of the exposed portion of the carrier transport layer; coating a quantum dot solution, hydrophilicity and the hydrophobicity of the quantum dot solution are respectively the same as those of the exposed portion of the carrier transport layer; and curing the quantum dot solution.