A unit pixel is provided. The unit pixel includes a transparent substrate, a first light blocking layer disposed on the transparent substrate and having windows that transmit light, an adhesive layer covering the first light blocking layer, a plurality of light emitting devices disposed on the adhesive layer to be arranged on the windows, and a second light blocking layer covering side surfaces of the light emitting devices.

A display apparatus includes a color filter substrate, a first encapsulation layer, a first bank layer, wavelength selective dimming patterns, color conversion patterns, a second encapsulation layer, a driving circuit substrate, a second bank layer and light emitting components. The wavelength selective dimming patterns are disposed in at least a portion of first openings of the first bank layer. The color conversion patterns are disposed in the first openings and on the wavelength selective dimming patterns. One wavelength selective dimming pattern includes a base material and scattering particles. The wavelength selective dimming pattern has a thickness within a range of 2 m to 10 m in a direction perpendicular to the color filter substrate. A volume ratio of the scattering particles to the wavelength selective dimming pattern falls within a range of 0.5% to 4.5%. Diameters of the scattering particles fall within a range of 80 nm to 200 nm.

A display device includes a substrate in which a plurality of sub pixels are defined; a pair of low potential power lines are in a sub pixel of the plurality of sub pixels; and a plurality of light emitting diodes that overlap an area between the pair of low potential power lines. Each of the plurality of light emitting diodes includes a first semiconductor layer; an emission layer; a second semiconductor layer; a first insulating film that encloses side surfaces of the first semiconductor layer, the emission layer, and the second semiconductor layer; a side electrode on the first insulating film; and a first electrode that is in contact with a bottom surface of the first semiconductor layer and a lower part of the side electrode.

Light-emitting diode (LED) packages and more particularly a light collector for light mixing in LED packages to improve the far field emission pattern (FFP) of the LED packages are disclosed. The LED package can include one or more LED chips with different wavelength ranges, and the light collector placed over the LED chips can have a reflective surface, save for a reduced aperture through which the light from the LED chips can be emitted after mixing in the light collector. The LED package can also include a lens to further improve the FFP. In an embodiment, the light collector can include diffuser material to facilitate the mixing of the light within the light collector. The LED package with the light collector mixes multiple emission point sources into a single point source, or reduced-area source, that considerably improves the FFP of multi-colored LED chips of the LED package.

The present disclosure discloses a display substrate, including a substrate, and a driver circuit, an insulation layer and a bonding electrode sequentially superposed on the substrate. The bonding electrode is configured to be connected to an anode and a cathode of a micro inorganic light-emitting diode chip to be bonded. The display substrate further includes an elastic layer sandwiched between the bonding electrode and the insulation layer, the elastic layer having an orthographic projection on the substrate covering at least an orthographic projection of the bonding electrode on the substrate. The present disclosure provides a display panel, including the above display substrate, and further including a micro inorganic light-emitting diode chip having an anode and a cathode thereof connected to the bonding electrode on the display substrate.

A color conversion panel includes light blocking members spaced apart from each other on a substrate; and a first color conversion layer, a second color conversion layer, and a transmission layer respectively disposed between the light blocking members, wherein the transmission layer includes first quantum dots, and the first quantum dots convert incident light into light having a wavelength in a range of about 480 nm to about 530 nm.

The present disclosure relates to a composition, a substrate and a preparation method of a light reflection layer. The composition comprises: a matrix material and an additive, the matrix material including a solvent, reactant molecules and a material with reflection function dispersed in the solvent, wherein the reactant molecules is capable of undergoing cross-linking reaction under a first preset condition, and include monomer molecules and/or prepolymer molecules; the additive including a filler material that is in the form of powder or microspheres, capable of being dispersed in the matrix material, and filled between the crosslinking points of any adjacent reactant molecules to block the crosslinking reaction of some adjacent reactant molecules under the first preset condition.

A light-emitting device includes: a light-emitting element configured to emit first light; a light-transmissive member covering an upper surface of the light-emitting element and including a wavelength conversion material configured to absorb a portion of the first light and emit second light; a light-scattering member disposed on the light-transmissive member, including a light-scattering material, and having a higher reflectance at a peak wavelength of the first light than at a peak wavelength of the second light; and a light-adjustment member located in or on the light-scattering member and having either (i) a higher absorptance at the peak wavelength of the second light than at the peak wavelength of the first light, or (ii) a higher reflectance at the peak wavelength of the second light than at the peak wavelength of the first light. A lateral surface of the light-transmissive member is exposed from the light-scattering member and the light-adjustment member.

The invention is in the field of immunotherapy. The present application provides modified RELA protein which are useful for inducing or promoting interferon expression by immune cells, in particular T cells. The invention enables the production of immune cells with an activated or enhanced interferon metabolism. The present application also relates to immune cells, in particular T cells, comprising and/or expressing a modified RELA protein according to the invention, such cells having an activated interferon metabolism. The present invention also provides in vitro and/or ex vivo method of preparing immune cells, in particular T cells, useful in immunotherapy. The invention also relates to methods for treating a patient, in particular a patient who has a cancer or an infectious disease, in particular an infection by a virus.

The present application provides identification, in vitro amplification, and application method of memory CD8 T cells specific for an antigen in a solid tumor-draining lymph node.